Isolation of strains with algicidal activity from South Taihu Lake in China and identification of active compounds

doi:10.3969/j.issn.1004-1524.20230541

Acta Agriculturae Zhejiangensis ›› 2024, Vol. 36 ›› Issue (5): 1124-1133.DOI: 10.3969/j.issn.1004-1524.20230541

• Environmental Science • Previous Articles Next Articles

Isolation of strains with algicidal activity from South Taihu Lake in China and identification of active compounds

CHEN Yaoyao(), LIU Xueping, ZHANG Shaoyong, WANG Jidong, WANG Ruijun, ZHANG Liqin^*()

Key Laboratory of Vector Biology and Pathogen Control of Zhejiang Province, College of Life Sciences, Huzhou University, Huzhou 313000, Zhejiang, China

Received:2023-04-26 Online:2024-05-25 Published:2024-05-29

Abstract

Abstract:

In the present study, culturable bacteria were isolated and purified from water samples of south Taihu Lake in four seasons by the dilution-plate method and modified isolation medium. These bacteria were identified using 16S rRNA gene sequence. Bacteria with algicidal activity against Microcystis aeruginosa were screened, and their active compounds were isolated and purified. It was shown that a total of 420 strains were isolated from water samples of south Taihu Lake in four seasons. They were classified into 192 species, 66 genera, 35 families, 20 orders, 9 classes and 4 phyla. Based on the isolated strain number, Flavobacterium, Pseudomonas, Brevundimonas and Bacillus were the majority at the genus level. There were 20 strains identified as potential new taxa by 16S rRNA gene sequence analysis. Seven strains showed obvious inhibitory activity against M. aeruginosa, of which Flavobacterium sp. 1-2-14 exhibited the strongest algicidal activity, as its inhibition rate reached 71.52% after co-cultured for 7 days. By adopting the tracing method of bioactivity, two compounds, cyclo (4-hydroxy-L-Pro-L-Leu) and pterodontriol B were isolated, and their inhibition rates against M. aeruginosa were 56.87%and 67.81% at 48 h, respectively.

Key words: south Taihu Lake, culturable bacteria, Microcystis aeruginosa, algicidal activity

CLC Number:

Q939.9
X524

CHEN Yaoyao, LIU Xueping, ZHANG Shaoyong, WANG Jidong, WANG Ruijun, ZHANG Liqin. Isolation of strains with algicidal activity from South Taihu Lake in China and identification of active compounds[J]. Acta Agriculturae Zhejiangensis, 2024, 36(5): 1124-1133.

Figures/Tables 6

References 37

[1]	沈国平, 韩睿, 缪增强, 等. 青藏高原4类典型水化学特征湖泊的细菌多样性差异及影响因素[J]. 生物多样性, 2022, 30(4): 88-102.
	SHEN G P, HAN R, MIAO Z Q, et al. Bacterial diversity differences and influence factors of four types of hydrochemical characteristic lakes in the Qinghai-Tibet Plateau[J]. Biodiversity Science, 2022, 30(4): 88-102. (in Chinese with English abstract)
[2]	陈小锋, 揣小明, 杨柳燕. 中国典型湖区湖泊富营养化现状、历史演变趋势及成因分析[J]. 生态与农村环境学报, 2014, 30(4): 438-443.
	CHEN X F, CHUAI X M, YANG L Y. Status quo, historical evolution and causes of eutrophication in lakes in typical lake regions of China[J]. Journal of Ecology and Rural Environment, 2014, 30(4): 438-443. (in Chinese with English abstract)
[3]	WOODHOUSE J N, KINSELA A S, COLLINS R N, et al. Microbial communities reflect temporal changes in cyanobacterial composition in a shallow ephemeral freshwater lake[J]. The ISME Journal, 2016, 10(6): 1337-1351.
[4]	WAN W J, ZHANG Y N, CHENG G J, et al. Dredging mitigates cyanobacterial bloom in eutrophic Lake Nanhu: shifts in associations between the bacterioplankton community and sediment biogeochemistry[J]. Environmental Research, 2020, 188: 109799.
[5]	SHI L M, CAI Y F, KONG F X, et al. Specific association between bacteria and buoyant Microcystis colonies compared with other bulk bacterial communities in the eutrophic Lake Taihu, China[J]. Environmental Microbiology Reports, 2012, 4(6): 669-678.
[6]	CAI H Y, JIANG H L, KRUMHOLZ L R, et al. Bacterial community composition of size-fractioned aggregates within the phycosphere of cyanobacterial blooms in a eutrophic freshwater lake[J]. PLoS One, 2014, 9(8): e102879.
[7]	TANG X M, CHAO J Y, GONG Y, et al. Spatiotemporal dynamics of bacterial community composition in large shallow eutrophic Lake Taihu: high overlap between free-living and particle-attached assemblages[J]. Limnology and Oceanography, 2017, 62(4): 1366-1382.
[8]	XU X B, YANG G S, TAN Y, et al. Ecological risk assessment of ecosystem services in the Taihu Lake Basin of China from 1985 to 2020[J]. Science of the Total Environment, 2016, 554/555: 7-16.
[9]	LI L, ZHAO X L, LIU D, et al. Occurrence and ecological risk assessment of PPCPs in typical inflow rivers of Taihu Lake, China[J]. Journal of Environmental Management, 2021, 285: 112176.
[10]	RODRIGUEZ-MOZAZ S, CHAMORRO S, MARTI E, et al. Occurrence of antibiotics and antibiotic resistance genes in hospital and urban wastewaters and their impact on the receiving river[J]. Water Research, 2015, 69: 234-242.
[11]	秦伯强, 杨桂军, 马健荣, 等. 太湖蓝藻水华“暴发”的动态特征及其机制[J]. 科学通报, 2016, 61(7): 759-770.
	QIN B Q, YANG G J, MA J R, et al. Dynamics of variability and mechanism of harmful cyanobacteria bloom in Lake Taihu, China[J]. Chinese Science Bulletin, 2016, 61(7): 759-770. (in Chinese with English abstract)
[12]	秦伯强. 浅水湖泊湖沼学与太湖富营养化控制研究[J]. 湖泊科学, 2020, 32(5): 1229-1243.
	QIN B Q. Shallow Lake limnology and control of eutrophication in Lake Taihu[J]. Journal of Lake Sciences, 2020, 32(5): 1229-1243. (in Chinese with English abstract)
[13]	史小丽, 杨瑾晟, 陈开宁, 等. 湖泊蓝藻水华防控方法综述[J]. 湖泊科学, 2022, 34(2): 349-375.
	SHI X L, YANG J S, CHEN K N, et al. Review on the control and mitigation strategies of lake cyanobacterial blooms[J]. Journal of Lake Sciences, 2022, 34(2): 349-375. (in Chinese with English abstract)
[14]	YANG M, WANG X R. Interactions between Microcystis aeruginosa and coexisting bisphenol A at different phosphorus levels[J]. Science of the Total Environment, 2019, 658: 439-448.
[15]	马健荣, 邓建明, 秦伯强, 等. 湖泊蓝藻水华发生机理研究进展[J]. 生态学报, 2013, 33(10): 3020-3030.
	MA J R, DENG J M, QIN B Q, et al. Progress and prospects on cyanobacteria bloom-forming mechanism in lakes[J]. Acta Ecologica Sinica, 2013, 33(10): 3020-3030. (in Chinese with English abstract)
[16]	朱广伟, 施坤, 李未, 等. 太湖蓝藻水华的年度情势预测方法探讨[J]. 湖泊科学, 2020, 32(5): 1421-1431.
	ZHU G W, SHI K, LI W, et al. Seasonal forecast method of cyanobacterial bloom intensity in eutrophic Lake Taihu, China[J]. Journal of Lake Sciences, 2020, 32(5): 1421-1431. (in Chinese with English abstract)
[17]	杨柳燕, 杨欣妍, 任丽曼, 等. 太湖蓝藻水华暴发机制与控制对策[J]. 湖泊科学, 2019, 31(1): 18-27.
	YANG L Y, YANG X Y, REN L M, et al. Mechanism and control strategy of cyanobacterial bloom in Lake Taihu[J]. Journal of Lake Sciences, 2019, 31(1): 18-27. (in Chinese with English abstract)
[18]	秦伯强, 朱广伟, 杨宏伟, 等. 新方法、新理论为太湖环境治理和生态修复提供科技支撑[J]. 中国科学院院刊, 2017, 32(6): 654-660.
	QIN B Q, ZHU G W, YANG H W, et al. Support environmental management and ecological restoration in Lake Taihu with new methods and new theories[J]. Bulletin of Chinese Academy of Sciences, 2017, 32(6): 654-660. (in Chinese with English abstract)
[19]	叶益华, 杨旭楠, 胡文哲, 等. 溶藻细菌的功能多样性及其菌剂应用[J]. 微生物学报, 2022, 62(4): 1171-1189.
	YE Y H, YANG X N, HU W Z, et al. Advances in functional diversity and application of algicidal bacteria[J]. Acta Microbiologica Sinica, 2022, 62(4): 1171-1189. (in Chinese with English abstract)
[20]	MEYER N, BIGALKE A, KAULFUB A, et al. Strategies and ecological roles of algicidal bacteria[J]. FEMS Microbiology Reviews, 2017, 41(6): 880-899.
[21]	陈莉婷, 左俊, 宋立荣, 等. 溶藻细菌筛选及溶藻活性物质对铜绿微囊藻生理活性的影响[J]. 水生生物学报, 2020, 44(3): 638-646.
	CHEN L T, ZUO J, SONG L R, et al. Screening of algae-lysing bacteria and the effects of algaelysing active substances on the physiological activities of Microcystis aeruginosa[J]. Acta Hydrobiologica Sinica, 2020, 44(3): 638-646. (in Chinese with English abstract)
[22]	HUA X H, LI J H, LI J J, et al. Selective inhibition of the cyanobacterium, Microcystis, by a Streptomyces sp.[J]. Biotechnology Letters, 2009, 31(10): 1531-1535.
[23]	叶益华, 杨旭楠, 陈进林, 等. 基于生态风险评估探究溶藻细菌2-4的抑藻特性[J]. 微生物学报, 2022, 62(9): 3631-3645.
	YE Y H, YANG X N, CHEN J L, et al. Algicidal characteristics of Pseudomonas 2-4: based on ecological risk assessment[J]. Acta Microbiologica Sinica, 2022, 62(9): 3631-3645. (in Chinese with English abstract)
[24]	焦彦凯, 严小军, 李小兵. 溶藻细菌及溶藻化合物研究进展[J]. 工业微生物, 2018, 48(4): 56-62.
	JIAO Y K, YAN X J, LI X B. Advances in research of algicidal bacteria and algae-lysing compounds[J]. Industrial Microbiology, 2018, 48(4): 56-62. (in Chinese with English abstract)
[25]	GUO X L, LIU X L, PAN J L, et al. Synergistic algicidal effect and mechanism of two diketopiperazines produced by Chryseobacterium sp. strain GLY-1106 on the harmful bloom-forming Microcystis aeruginosa[J]. Scientific Reports, 2015, 5: 14720.
[26]	STANIER R Y, KUNISAWA R, MANDEL M, et al. Purification and properties of unicellular blue-green algae (order Chroococcales)[J]. Bacteriological Reviews, 1971, 35(2): 171-205.
[27]	李菲, 高程海, 余炼, 等. 川蔓藻内生及根际细菌多样性与抑菌活性研究[J]. 广西植物, 2018, 38(7): 924-933.
	LI F, GAO C H, YU L, et al. Diversity and antifungal activity of endophytic and rhizospheric bacteria isolated from Ruppia maritima[J]. Guihaia, 2018, 38(7): 924-933. (in Chinese with English abstract)
[28]	KUMAR S, STECHER G, TAMURA K. MEGA7: molecular evolutionary genetics analysis version 7.0 for bigger datasets[J]. Molecular Biology and Evolution, 2016, 33(7): 1870-1874.
[29]	林少君, 贺立静, 黄沛生, 等. 浮游植物中叶绿素a提取方法的比较与改进[J]. 生态科学, 2005, 24(1): 9-11.
	LIN S J, HE L J, HUANG P S, et al. Comparison and improvement on the extraction method for chlorophyll a in phytoplankton[J]. Ecologic Science, 2005, 24(1): 9-11. (in Chinese with English abstract)
[30]	王德铭, 王明霞, 罗森源. 水生生物监测手册[M]. 南京: 东南大学出版社, 1993.
[31]	NALLI Y, GUPTA S, KHAJURIA V, et al. TNF-α and IL-6 inhibitory effects of cyclic dipeptides isolated from marine bacteria Streptomyces sp[J]. Medicinal Chemistry Research, 2017, 26(1): 93-100.
[32]	CRONAN J M, DAVIDSON T R, SINGLETON F L, et al. Plant growth promoters isolated from a marine bacterium associated with Palythoa sp[J]. Natural Product Letters, 1998, 11(4): 271-278.
[33]	HU J F, BAI S P, JIA Z J. Eudesmane sesquiterpenes from Artemisia eriopoda[J]. Phytochemistry, 1996, 43(4): 815-817.
[34]	吴秀红, 张新中, 周永灿, 等. 关于芽孢杆菌(Bacillus)应用概述[J]. 现代渔业信息, 2007, 22(7): 16-18.
	WU X H, ZHANG X Z, ZHOU Y C, et al. Outline of related Bacillus spp[J]. Modern Fisheries Information, 2007, 22(7): 16-18. (in Chinese)
[35]	KAZUOKA T, OIKAWA T, MURAOKA I, et al. A cold-active and thermostable alcohol dehydrogenase of a psychrotorelant from Antarctic seawater, Flavobacterium frigidimaris KUC-1[J]. Extremophiles, 2007, 11(2): 257-267.
[36]	郑宁宁, 孙丽, 丁宁, 等. 有害微藻抑藻细菌多样性及抑藻机制研究进展[J]. 微生物学通报, 2019, 46(5): 1204-1219.
	ZHENG N N, SUN L, DING N, et al. Diversity of algicidal bacteria associated with harmful microalgae and the algicidal mechanisms[J]. Microbiology China, 2019, 46(5): 1204-1219. (in Chinese with English abstract)
[37]	QIN B Q, PAERL H W, BROOKES J D, et al. Why Lake Taihu continues to be plagued with cyanobacterial blooms through 10 years (2007-2017) efforts[J]. Science Bulletin, 2019, 64(6): 354-356.

门 Phylum	纲 Class	目 Order	科 Family	属 Genus	种数量 Species number	菌株数量 Strain number
变形菌门 Pseudomonadota	β-变形菌纲 Betaproteobacteria	伯克氏菌目 Burkholderiales	产碱菌科 Alcaligenaceae	产碱菌属Alcaligenes	1	10
			丛毛单胞菌科 Comamonadaceae	氢噬胞菌属Hydrogenophaga Simplicispira	3 1	5 2
				食酸菌属Acidovorax	3	4
				Curvibacter	1	2
				Aquincola	1	1
				Inhella	1	1
				大单胞菌属Macromonas	1	1
				Kinneretia	1	1
				Ramlibacter	1	1
			草酸杆菌科	紫色杆菌属Janthinobacterium	5	6
			Oxalobacteraceae	马赛菌属Massilia	1	2
				Undibacterium	1	2
			伯克氏菌科 Burkholderiaceae	Ralstonia	2	9
		奈瑟菌目	奈瑟氏菌科	Aquella	1	1
		Neisseriales	Neisseriaceae	福格斯氏菌属Vogesella	1	1
	α-变形菌纲	鞘脂单胞菌目	Sphingosinicellaceae	Sandarakinorhabdus	1	2
	Alphaproteobacteria	Sphingomonadales	赤杆菌科 Erythrobacteraceae	赤杆菌属Erythrobacter	4	16
			鞘脂单胞菌科	新鞘脂属Novosphingobium	7	10
			Sphingomonadaceae	鞘氨醇单胞菌属Sphingomonas	4	7
				鞘脂单胞菌属Sphingopyxis	4	6
				Sphingorhabdus	5	16
		柄杆菌目	柄杆菌科	短波单胞菌属Brevundimonas	10	21
		Caulobacterales	Caulobacteraceae	柄杆菌属Caulobacter	4	11
				PAC001798_g	1	1
				苯基杆菌属Phenylobacterium	1	4
		根瘤菌目	Boseaceae	包西氏菌属Bosea	2	3
		Rhizobiales	甲基杆菌科 Methylobacteriaceae	甲基杆菌属Methylobacterium	2	2
			硝化杆菌科 Nitrobacteraceae	阿菲波菌属Afipia	1	1
			叶杆菌科 Phyllobacteriaceae	中慢生根瘤菌属Mesorhizobium	1	1
			根瘤菌科 Rhizobiaceae	根瘤菌属Rhizobium	2	6
			黄色杆菌科 Xanthobacteraceae	黄色杆菌属Xanthobacter	1	1
		红杆菌目 Rhodobacterales	红杆菌科 Rhodobacteraceae	芽殖杆菌属 Gemmobacter	3	4
		红螺菌目	Azospirillaceae	Elstera	1	1
		Rhodospirillales		Niveispirillum	1	1
	γ-变形菌纲 Gammaproteobacteria	气单胞菌目 Aeromonadales	气单胞菌科 Aeromonadaceae	气单胞菌属Aeromonas	1	1
		着色菌目 Chromatiales	着色菌科 Chromatiaceae	Pararheinheimera	3	7
		溶杆菌目	Lysobacteraceae	溶杆菌属Lysobacter	2	5
		Lysobacterales		Pseudoxanthomonas	2	7
				Silanimonas	1	1
				寡养单胞菌属Stenotrophomonas	1	2
		假单胞菌目 Pseudomonadales	莫拉菌科 Moraxellaceae	不动杆菌属Acinetobacter	1	1
			假单胞菌科 Pseudomonadaceae	假单胞菌属Pseudomonas	24	56
拟杆菌门 Bacteroidota	噬几丁质菌纲 Chitinophagia	噬几丁质菌目 Chitinophagales	噬几丁质菌科 Chitinophagaceae	Lacibacter	1	1
	黄杆菌纲 Flavobacteriia	黄杆菌目 Flavobacteriales	黄杆菌科 Flavobacteriaceae	黄杆菌属Flavobacterium	21	77
			威克斯氏菌科	Cloacibacterium	1	2
			Weeksellaceae	伊丽莎白菌属Elizabethkingia	1	1
	鞘脂杆菌纲 Sphingobacteriia	鞘氨醇杆菌目 Sphingobacteriales	鞘脂杆菌科 Sphingobacteriaceae	土地杆菌属Pedobacter	1	2
芽孢杆菌门	芽孢杆菌纲	核衣细菌目	芽孢杆菌科	芽孢杆菌属Bacillus	12	29
Bacillota	Bacilli	Caryophanales	Bacillaceae	Falsibacillus	1	1
				Fictibacillus	3	9
				Niallia	2	2
				Priestia	2	5
				Rossellomorea	3	4
				微小杆菌属Exiguobacterium	1	2
			Caryophanaceae	Lysinibacillus	1	2
				Metasolibacillus	2	4
				Rummeliibacillus	1	1
			类芽孢杆菌科 Paenibacillaceae	短杆菌属Brevibacillus	1	1
	梭菌纲 Clostridia	Eubacteriales	毛螺菌科 Lachnospiraceae	毛螺菌属Lachnospira	1	1
放线菌门	放线菌纲	微球菌目	Dermabacteraceae	Brachybacterium	1	1
Actinomycetota	Actinomycetes	Micrococcales	微杆菌科	Agrococcus	1	1
			Microbacteriaceae	微杆菌属Microbacterium	8	9
		Micromonosporales	小单孢菌科 Micromonosporaceae	小单孢菌属Micromonospora	2	5
		分枝杆菌目 Mycobacteriales	Mycobacteriaceae 链霉菌科	分枝杆菌属Mycolicibacterium 链霉菌属Streptomyces	6 4	13 4
		Kitasatosporales	Streptomycetaceae

门 Phylum	纲 Class	目 Order	科 Family	属 Genus	种数量 Species number	菌株数量 Strain number
变形菌门 Pseudomonadota	β-变形菌纲 Betaproteobacteria	伯克氏菌目 Burkholderiales	产碱菌科 Alcaligenaceae	产碱菌属Alcaligenes	1	10
			丛毛单胞菌科 Comamonadaceae	氢噬胞菌属Hydrogenophaga Simplicispira	3 1	5 2
				食酸菌属Acidovorax	3	4
				Curvibacter	1	2
				Aquincola	1	1
				Inhella	1	1
				大单胞菌属Macromonas	1	1
				Kinneretia	1	1
				Ramlibacter	1	1
			草酸杆菌科	紫色杆菌属Janthinobacterium	5	6
			Oxalobacteraceae	马赛菌属Massilia	1	2
				Undibacterium	1	2
			伯克氏菌科 Burkholderiaceae	Ralstonia	2	9
		奈瑟菌目	奈瑟氏菌科	Aquella	1	1
		Neisseriales	Neisseriaceae	福格斯氏菌属Vogesella	1	1
	α-变形菌纲	鞘脂单胞菌目	Sphingosinicellaceae	Sandarakinorhabdus	1	2
	Alphaproteobacteria	Sphingomonadales	赤杆菌科 Erythrobacteraceae	赤杆菌属Erythrobacter	4	16
			鞘脂单胞菌科	新鞘脂属Novosphingobium	7	10
			Sphingomonadaceae	鞘氨醇单胞菌属Sphingomonas	4	7
				鞘脂单胞菌属Sphingopyxis	4	6
				Sphingorhabdus	5	16
		柄杆菌目	柄杆菌科	短波单胞菌属Brevundimonas	10	21
		Caulobacterales	Caulobacteraceae	柄杆菌属Caulobacter	4	11
				PAC001798_g	1	1
				苯基杆菌属Phenylobacterium	1	4
		根瘤菌目	Boseaceae	包西氏菌属Bosea	2	3
		Rhizobiales	甲基杆菌科 Methylobacteriaceae	甲基杆菌属Methylobacterium	2	2
			硝化杆菌科 Nitrobacteraceae	阿菲波菌属Afipia	1	1
			叶杆菌科 Phyllobacteriaceae	中慢生根瘤菌属Mesorhizobium	1	1
			根瘤菌科 Rhizobiaceae	根瘤菌属Rhizobium	2	6
			黄色杆菌科 Xanthobacteraceae	黄色杆菌属Xanthobacter	1	1
		红杆菌目 Rhodobacterales	红杆菌科 Rhodobacteraceae	芽殖杆菌属 Gemmobacter	3	4
		红螺菌目	Azospirillaceae	Elstera	1	1
		Rhodospirillales		Niveispirillum	1	1
	γ-变形菌纲 Gammaproteobacteria	气单胞菌目 Aeromonadales	气单胞菌科 Aeromonadaceae	气单胞菌属Aeromonas	1	1
		着色菌目 Chromatiales	着色菌科 Chromatiaceae	Pararheinheimera	3	7
		溶杆菌目	Lysobacteraceae	溶杆菌属Lysobacter	2	5
		Lysobacterales		Pseudoxanthomonas	2	7
				Silanimonas	1	1
				寡养单胞菌属Stenotrophomonas	1	2
		假单胞菌目 Pseudomonadales	莫拉菌科 Moraxellaceae	不动杆菌属Acinetobacter	1	1
			假单胞菌科 Pseudomonadaceae	假单胞菌属Pseudomonas	24	56
拟杆菌门 Bacteroidota	噬几丁质菌纲 Chitinophagia	噬几丁质菌目 Chitinophagales	噬几丁质菌科 Chitinophagaceae	Lacibacter	1	1
	黄杆菌纲 Flavobacteriia	黄杆菌目 Flavobacteriales	黄杆菌科 Flavobacteriaceae	黄杆菌属Flavobacterium	21	77
			威克斯氏菌科	Cloacibacterium	1	2
			Weeksellaceae	伊丽莎白菌属Elizabethkingia	1	1
	鞘脂杆菌纲 Sphingobacteriia	鞘氨醇杆菌目 Sphingobacteriales	鞘脂杆菌科 Sphingobacteriaceae	土地杆菌属Pedobacter	1	2
芽孢杆菌门	芽孢杆菌纲	核衣细菌目	芽孢杆菌科	芽孢杆菌属Bacillus	12	29
Bacillota	Bacilli	Caryophanales	Bacillaceae	Falsibacillus	1	1
				Fictibacillus	3	9
				Niallia	2	2
				Priestia	2	5
				Rossellomorea	3	4
				微小杆菌属Exiguobacterium	1	2
			Caryophanaceae	Lysinibacillus	1	2
				Metasolibacillus	2	4
				Rummeliibacillus	1	1
			类芽孢杆菌科 Paenibacillaceae	短杆菌属Brevibacillus	1	1
	梭菌纲 Clostridia	Eubacteriales	毛螺菌科 Lachnospiraceae	毛螺菌属Lachnospira	1	1
放线菌门	放线菌纲	微球菌目	Dermabacteraceae	Brachybacterium	1	1
Actinomycetota	Actinomycetes	Micrococcales	微杆菌科	Agrococcus	1	1
			Microbacteriaceae	微杆菌属Microbacterium	8	9
		Micromonosporales	小单孢菌科 Micromonosporaceae	小单孢菌属Micromonospora	2	5
		分枝杆菌目 Mycobacteriales	Mycobacteriaceae 链霉菌科	分枝杆菌属Mycolicibacterium 链霉菌属Streptomyces	6 4	13 4
		Kitasatosporales	Streptomycetaceae

菌株编码 Strain No.	最相似菌株的种属名(登录号) The closest typical strain (Accession No.)	序列相似度 Sequence similarity/%
1-2-14	Flavobacterium cupreum CCM 8825^T(MH100899)	98.20
1-1-6	Flavobacterium ureilyticum S-42^T(KY117464)	97.18
1-2-20	Simplicispira lacusdiani CPCC 100842^T(MG708102)	98.55
1-2-29	Rheinheimera chironomi K19414^T(DQ298025)	98.46
2-1-14	Novosphingobium taihuense T3-B9^T(AY500142)	97.93
2-1-18	Flavobacterium buctense T7^T(KP744923)	97.90
3-2-16	Flavobacterium phycosphaerae MK012^T(MN559947)	97.64
4-1-13	Flavobacterium dankookense DSM 25687^T(jgi.1108032)	97.63
4-2-2	Flavobacterium granuli DSM 17797^T(jgi.1107693)	98.54
4-2-7	Flavobacterium terrigena DSM 17934^T(FNYA01000017)	97.63
4-2-9	Flavobacterium saccharophilum DSM 1811^T(jgi.1107675)	97.63
5-2-2	Flavobacterium silvisoli RD-2-33^T(SJPE01000025)	98.15
D-12	Flavobacterium cheonhonense ARSA-15^T(GU295972)	97.32
E-18	Caulobacter soli Ji-3-8^T(MT026974)	94.19
T1-10	Flavobacterium cheniae NJ-26^T(EF407880)	97.65
T2-8	Rheinheimera aquatica GR5^T(GQ168584)	98.40
T2-10	Flavobacterium filum EMB34^T(DQ372981)	97.87
T5-7	Flavobacterium tiangeerense 563^T(EU036219)	96.55
H1-31	Ralstonia mannitolilytica LMG 6866^T(AJ270258)	98.38
H5-31	Aquincola tertiaricarbonis L10^T(DQ656489)	98.55

菌株编码 Strain No.	最相似菌株的种属名(登录号) The closest typical strain (Accession No.)	序列相似度 Sequence similarity/%
1-2-14	Flavobacterium cupreum CCM 8825^T(MH100899)	98.20
1-1-6	Flavobacterium ureilyticum S-42^T(KY117464)	97.18
1-2-20	Simplicispira lacusdiani CPCC 100842^T(MG708102)	98.55
1-2-29	Rheinheimera chironomi K19414^T(DQ298025)	98.46
2-1-14	Novosphingobium taihuense T3-B9^T(AY500142)	97.93
2-1-18	Flavobacterium buctense T7^T(KP744923)	97.90
3-2-16	Flavobacterium phycosphaerae MK012^T(MN559947)	97.64
4-1-13	Flavobacterium dankookense DSM 25687^T(jgi.1108032)	97.63
4-2-2	Flavobacterium granuli DSM 17797^T(jgi.1107693)	98.54
4-2-7	Flavobacterium terrigena DSM 17934^T(FNYA01000017)	97.63
4-2-9	Flavobacterium saccharophilum DSM 1811^T(jgi.1107675)	97.63
5-2-2	Flavobacterium silvisoli RD-2-33^T(SJPE01000025)	98.15
D-12	Flavobacterium cheonhonense ARSA-15^T(GU295972)	97.32
E-18	Caulobacter soli Ji-3-8^T(MT026974)	94.19
T1-10	Flavobacterium cheniae NJ-26^T(EF407880)	97.65
T2-8	Rheinheimera aquatica GR5^T(GQ168584)	98.40
T2-10	Flavobacterium filum EMB34^T(DQ372981)	97.87
T5-7	Flavobacterium tiangeerense 563^T(EU036219)	96.55
H1-31	Ralstonia mannitolilytica LMG 6866^T(AJ270258)	98.38
H5-31	Aquincola tertiaricarbonis L10^T(DQ656489)	98.55

菌株编码 Strain No.	相似菌株种属名(登录号) The closest typical strain (Accession No.)	序列相似度 Sequence similarity/%	抑制率 Inhibition rate/%
C-1	Priestia aryabhattai B8W22^T(EF114313)	100.00	42.75±1.74
2-1-3	Flavobacterium granuli DSM 17797^T(jgi.1107693)	99.40	45.01±2.70
H4-20	Sphingomonas leidyi ATCC 15260^T(AJ227812)	99.88	47.80±1.41
H1-13	Inhella inkyongensis IMCC1713^T(DQ664238)	99.43	58.75±2.55
T3-11	Brevundimonas terrae KSL-145^T(DQ335215)	99.33	64.37±6.43
A-1	Fictibacillus barbaricus V2-BIII-A2^T(AJ422145)	100.00	65.89±0.85
1-2-14	Flavobacterium cupreum CCM 8825^T(MH100899)	98.20	71.52±1.26

Isolation of strains with algicidal activity from South Taihu Lake in China and identification of active compounds

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 6

References 37

Related Articles 1

Recommended Articles

Metrics

Comments

化合物 Compound	不同浓度(mg·L^-1)处理48 h的抑藻率The inhibition rates under different concentration(mg·L^-1) treatment for 48 h
化合物 Compound	0.5	1	2
1	20.34±2.13	40.27±2.99	56.87±1.67
2	24.11±2.07	47.65±3.89	67.81±3.35