Population structure and genetic diversity of Culter recurviceps revealed by multi-loci

doi:10.17520/biods.2021166

Abstract

Abstract:

Aim: Culter recurviceps (Cypriniformes: Cyprinidae) is an economic fish species in South China. Nevertheless, the resources of this species declined rapidly during recent years due to water conservancy, overfishing, and environmental pollution. Therefore, more attention and conservation measure are needed for this species. Population genetic analyses can both reveal genetic diversity and population structure of particular species and provide implications for management and conservation of these species. The aim of this study is to investigate the population genetic structure and genetic diversity of C. recurviceps and further provide implications for the preservation and reasonable development of its resources.
Methods: We collected 207 individuals from 23 populations in the drainages in Southern China. With respect to the 207 individuals, two mitochondrial genes (Cytb and ND2) were sequenced and the corresponding mitochondrial COI gene was obtained from the Barcode of Life Data System (BOLD) database. We then combined the three genes to study the genetic structure and genetic diversity of C. recurviceps populations. Multiple analyses including phylogenetic analysis, divergence time estimates, haplotype network, population genetic analyses, and Mantel tests were employed.
Results: Phylogenetic analysis and haplotype network revealed that C. recurviceps populations contained three lineages (I, II and III). The members of lineages I and III contained populations from the Pearl River and the representatives of lineage II comprised of populations from the Hainan Island. Divergence time estimates indicated the three lineages were split between 0.028 and 0.251 million years ago (Ma), suggesting that Pleistocene climate change may have triggered the divergence of the three lineages. Population genetic analyses showed significant genetic differentiation (F_ST = 0.511, P < 0.001) and isolation by distance pattern (R = 0.348, P = 0.0010) was observed among C. recurviceps populations. Demographic analyses revealed that C. recurviceps populations might experience population expansion during 0.010-0.025 Ma, implying that Pleistocene climatic fluctuations have influenced the population size and distribution of C.recurviceps populations.
Conclusion: We observed that C. recurviceps populations in South China consisted of three mitochondrial lineages. Pleistocene climate changes have not only triggered the divergences of the three lineages, but also influenced the demographic history of C. recurviceps populations. Furthermore, spatial distance acted as a key factor that improved the population differentiation among C. recurviceps populations.

Key words: Culter recurviceps, population structure, genetic diversity, multi-loci

Denggao Xiang, Yuefei Li, Xinhui Li, Weitao Chen, Xiuhui Ma. Population structure and genetic diversity of Culter recurviceps revealed by multi-loci[J]. Biodiv Sci, 2021, 29(11): 1505-1512.

Add to citation manager EndNote|Ris|BibTeX

URL: https://www.biodiversity-science.net/EN/10.17520/biods.2021166

https://www.biodiversity-science.net/EN/Y2021/V29/I11/1505

Figures/Tables 6

References 28

[1]	Avise JC, Arnold J, Ball RM, Bermingham E, Lamb T, Neigel JE, Reeb CA, Saunders NC (1987) Intraspecific phylogeography: The mitochondrial DNA bridge between population genetics and systematics. Annual Review of Ecology and Systematics, 18, 489-522. DOI URL
[2]	Chen WT, Li C, Chen FC, Li YF, Yang JP, Li J, Li XH (2020) Phylogeographic analyses of a migratory freshwater fish (Megalobrama terminalis) reveal a shallow genetic structure and pronounced effects of sea-level changes. Gene, 737, 144478.
[3]	Chen XL, Chiang TY, Lin HD, Zheng HS, Shao KT, Zhang Q, Hsu KC (2007) Mitochondrial DNA phylogeography of Glyptothorax fokiensis and Glyptothorax hainanensis in Asia. Journal of Fish Biology, 70, 75-93. DOI URL
[4]	Drummond AJ, Rambaut A (2007) BEAST: Bayesian evolutionary analysis by sampling trees. BMC Evolutionary Biology, 7, 214. PMID
[5]	Durand JD, Tsigenopoulos CS, Ünlü E, Berrebi P (2002) Erratum to “Phylogeny and Biogeography of the Family Cyprinidae in the Middle East Inferred from Cytochrome b DNA-Evolutionary Significance of This Region”. Molecular Phylogenetics and Evolution, 22, 91-100. PMID
[6]	Excoffier L, Lischer HEL (2010) Arlequin suite ver 3.5: A new series of programs to perform population genetics analyses under Linux and Windows. Molecular Ecology Resources, 10, 564-567. DOI PMID
[7]	Fu YX (1996) Estimating the age of the common ancestor of a DNA sample using the number of segregating sites. Genetics, 144, 829-838. PMID
[8]	Gascoyne M, Benjamin GJ, Schwarcz HP, Ford DC (1979) Sea-level lowering during the Illinoian glaciation: Evidence from a Bahama “Blue Hole”. Science, 205, 806-808. PMID
[9]	Hey J (2010) Isolation with migration models for more than two populations. Molecular Biology and Evolution, 27, 905-920. DOI URL
[10]	Ketmaier V, Bianco PG, Cobolli M, Krivokapic M, Caniglia R,De Matthaeis E (2004) Molecular phylogeny of two lineages of Leuciscinae cyprinids (Telestes and Scardinius) from the peri-Mediterranean area based on cytochrome b data. Molecular Phylogenetics and Evolution, 32, 1061-1071. PMID
[11]	Kimura M (1980) A simple method for estimating evolutionary rates of base substitutions through comparative studies of nucleotide sequences. Journal of Molecular Evolution, 16, 111-120. PMID
[12]	Li J, Li XH, Tan XC, Li YF, He MF, Luo JR, Lin JZ, Su SF (2009) Species diversity of fish community of Provincial Xijiang River Rare Fishes Natural Reserve in Zhaoqing City, Guangdong Province. Journal of Lake Sciences, 21, 556-562. (in Chinese with English abstract) DOI URL
	[ 李捷, 李新辉, 谭细畅, 李跃飞, 何美峰, 罗建仁, 林建志, 苏少芳 (2009) 广东肇庆西江珍稀鱼类省级自然保护区鱼类多样性. 湖泊科学, 21, 556-562.]
[13]	Librado P, Rozas J (2009) DnaSP v5: A software for comprehensive analysis of DNA polymorphism data. Bioinformatics, 25, 1451-1452. DOI PMID
[14]	Manel S, Schwartz MK, Luikart G, Taberlet P (2003) Landscape genetics: Combining landscape ecology and population genetics. Trends in Ecology & Evolution, 18, 189-197. DOI URL
[15]	Nylander JAA, Ronquist F, Huelsenbeck JP, Nieves-Aldrey J (2004) Bayesian phylogenetic analysis of combined data. Systematic Biology, 53, 47-67. PMID
[16]	Qiu CF, Lin YG, Qing N, Zhao J, Chen XL (2008) Genetic variation and phylogeography of Micronoemacheilus pulcher populations among basin systems between western South China and Hainan Island. Acta Zoologica Sinica, 54, 805-813. (in Chinese with English abstract)
	[ 丘城锋, 林岳光, 庆宁, 赵俊, 陈湘粦 (2008) 华南西部及海南岛美丽小条鳅种群遗传变异与亲缘地理. 动物学报, 54, 805-813.]
[17]	Ronquist F, Huelsenbeck JP (2003) MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics, 19, 1572-1574. PMID
[18]	Salzburger W, Ewing GB, Von Haeseler A (2011) The performance of phylogenetic algorithms in estimating haplotype genealogies with migration. Molecular Ecology, 20, 1952-1963.
[19]	Shuai FM, Li XF, Liu QF, Li YF, Yang JP, Li J, Chen FC (2017) Spatial patterns of fish diversity and distribution in the Pearl River. Acta Ecologica Sinica, 37, 3182-3192. (in Chinese with English abstract)
	[ 帅方敏, 李新辉, 刘乾甫, 李跃飞, 杨计平, 李捷, 陈方灿 (2017) 珠江水系鱼类群落多样性空间分布格局. 生态学报, 37, 3182-3192.]
[20]	Tajima F (1989) Statistical method for testing the neutral mutation hypothesis by DNA polymorphism. Genetics, 123, 585-595. PMID
[21]	Tamura K, Stecher G, Peterson D, Filipski A, Kumar S (2013) MEGA6: Molecular evolutionary genetics analysis version 6.0. Molecular Biology and Evolution, 30, 2725-2729. DOI URL
[22]	Wright S (1943) Isolation by distance. Genetics, 28, 114-138. PMID
[23]	Xie G, Pang SX, Xu SY, Ye X, Qi BL, Pan DB (1998) Artificial reproduction and embryo development of Culter recurviceps. Fisheries Science and Technology, (5), 23-25. (in Chinese)
	[ 谢刚, 庞世勋, 许淑英, 叶星, 祁宝仑, 潘德博 (1998) 海南红鲌人工繁殖和胚胎发育. 水产科技, (5), 23-25.]
[24]	Xu SY, Xie G, Qi BL, Ye X, Pang SX (2001) Study on the sensitivity of Culter recurviceps to aquatic drugs. Reservoir Fisheries, 21(1), 36-36. (in Chinese)
	[ 许淑英, 谢刚, 祁宝仑, 叶星, 庞世勋 (2001) 海南红鲌对水产药物的敏感性研究. 水利渔业, 21(1), 36-37.]
[25]	Xuan ZY, Jiang T, Liu HB, Chen XB, Yang J (2020) Genetic divergence of Coilia nasus taihuensis and Coilia brachygnathus populations based on the mitochondrial Cyt-b gene. Progress in Fishery Sciences, 41(4), 33-40. (in Chinese with English abstract)
	[ 轩中亚, 姜涛, 刘洪波, 陈修报, 杨健 (2020) 基于线粒体Cyt-b序列的太湖湖鲚与短颌鲚种群遗传分析. 渔业科学进展, 41(4), 33-40.]
[26]	Yang JQ, Hsu KC, Liu ZZ, Su LW, Kuo PH, Tang WQ, Zhou ZC, Liu D, Bao BL, Lin HD (2016) The population history of Garra orientalis (Teleostei: Cyprinidae) using mitochondrial DNA and microsatellite data with approximate Bayesian computation. BMC Evolutionary Biology, 16, 73. DOI URL
[27]	Zheng CY (1989) The Ichthyography of the Pearl River. Science Press, Beijing. (in Chinese)
	[ 郑慈英 (1989) 珠江鱼类志. 科学出版社, 北京.]
[28]	Zhou ZX, Liu B, Gong J, Bai YL, Yang JY, Xu P (2020) Phylogeny and population genetics of species in Takifugu genus based on mitochondrial genome. Journal of Fisheries of China, 44, 1792-1803. (in Chinese with English abstract)
	[ 周志雄, 刘波, 宫杰, 白玉麟, 阳俊逸, 徐鹏 (2020) 基于线粒体基因组的东方鲀属系统发育学及群体遗传学. 水产学报, 44, 1792-1803.]

群体 Population	样本量 Sample size	经纬度 Locality
海南岛水系 Hainan Island drainage
白沙 Baisha (BS)	33	19˚13′ N/109˚26′ E
南丰 Nanfeng (NF)	15	19˚25′ N/109˚33′ E
定安 Dingan (DA)	4	19˚40′ N/110˚21′ E
珠江水系 Pearl River drainage
从江 Congjiang (CJ)	9	25˚44′ N/108˚55′ E
崇左 Chongzuo (CZ)	14	22˚16′ N/107˚22′ E
桂平 Guiping (GP)	14	23˚23′ N/110˚04′ E
武宣 Wuxuan (WX)	2	23˚35′ N/109˚40′ E
古竹 Guzhu (GZ)	16	23˚30′ N/114˚42′ E
惠州 Huizhou (HZ)	11	23˚06′ N/114˚24′ E
江门 Jiangmen (JM)	4	22˚34′ N/113˚07′ E
横沥 Hengli (HL)	1	22˚43′ N/113˚29′ E
开平 Kaiping (KP)	5	22˚22′ N/112˚41′ E
柳州 Liuzhou (LZ)	5	24˚18′ N/109˚23′ E
柳城 Liucheng (LC)	8	24˚38′ N/109˚14′ E
南宁 Nanning (NN)	7	22˚46′ N/108˚21′ E
清远 Qingyuan (QY)	5	23˚37′ N/113˚03′ E
梧州 Wuzhou (WZ)	13	23˚25′ N/111˚16′ E
濛江 Mengjiang (MJ)	1	23˚27′ N/110˚44′ E
永福 Yongfu (YF)	12	24˚59′ N/109˚59′ E
郁南 Yunan (YN)	11	23˚14′ N/111˚31′ E
思林 Silin (SL)	12	23˚30′ N/107˚20′ E
韶关 Shaoguan (SG)	2	24˚47′ N/113˚35′ E
平乐 Pingle (PL)	3	24˚37′ N/110˚38′ E
总计 Total	207

群体 Population	样本量 Sample size	经纬度 Locality
海南岛水系 Hainan Island drainage
白沙 Baisha (BS)	33	19˚13′ N/109˚26′ E
南丰 Nanfeng (NF)	15	19˚25′ N/109˚33′ E
定安 Dingan (DA)	4	19˚40′ N/110˚21′ E
珠江水系 Pearl River drainage
从江 Congjiang (CJ)	9	25˚44′ N/108˚55′ E
崇左 Chongzuo (CZ)	14	22˚16′ N/107˚22′ E
桂平 Guiping (GP)	14	23˚23′ N/110˚04′ E
武宣 Wuxuan (WX)	2	23˚35′ N/109˚40′ E
古竹 Guzhu (GZ)	16	23˚30′ N/114˚42′ E
惠州 Huizhou (HZ)	11	23˚06′ N/114˚24′ E
江门 Jiangmen (JM)	4	22˚34′ N/113˚07′ E
横沥 Hengli (HL)	1	22˚43′ N/113˚29′ E
开平 Kaiping (KP)	5	22˚22′ N/112˚41′ E
柳州 Liuzhou (LZ)	5	24˚18′ N/109˚23′ E
柳城 Liucheng (LC)	8	24˚38′ N/109˚14′ E
南宁 Nanning (NN)	7	22˚46′ N/108˚21′ E
清远 Qingyuan (QY)	5	23˚37′ N/113˚03′ E
梧州 Wuzhou (WZ)	13	23˚25′ N/111˚16′ E
濛江 Mengjiang (MJ)	1	23˚27′ N/110˚44′ E
永福 Yongfu (YF)	12	24˚59′ N/109˚59′ E
郁南 Yunan (YN)	11	23˚14′ N/111˚31′ E
思林 Silin (SL)	12	23˚30′ N/107˚20′ E
韶关 Shaoguan (SG)	2	24˚47′ N/113˚35′ E
平乐 Pingle (PL)	3	24˚37′ N/110˚38′ E
总计 Total	207

群体 Population	单倍型数 Number of haplotype	单倍型多样性 Haplotype diversity	核苷酸多样性 Nucleotide diversity	中性检测 Neutrality tests
群体 Population	单倍型数 Number of haplotype	单倍型多样性 Haplotype diversity	核苷酸多样性 Nucleotide diversity	Tajima’s D	Fu’s Fs
BS	7	0.383 (± 0.107)	0.0002 (±0.0001)	-1.75856**	-6.19981***
CJ	4	0.806 (± 0.089)	0.0021 (±0.0003)	1.29983	2.70828
CZ	7	0.879 (± 0.058)	0.0009 (±0.0001)	0.01278	-1.77070
GP	10	0.923 (± 0.060)	0.0011 (±0.0001)	-0.27622	-5.21979***
GZ	10	0.917 (± 0.049)	0.0013 (±0.0003)	-1.10830	-3.75174*
HZ	7	0.891 (± 0.074)	0.0014 (±0.0002)	-1.41142	-1.25974
KP	4	0.900 (± 0.161)	0.0019 (±0.0008)	-0.92693	0.35685
LZ	3	0.800 (± 0.164)	0.0026 (±0.0006)	1.25408	2.74649
LC	5	0.893 (± 0.086)	0.0018 (±0.0005)	-0.66317	0.49798
NF	2	0.133 (± 0.112)	0.0001 (±0.0001)	-1.15945	-0.64899
NN	3	0.762 (± 0.115)	0.0006 (±0.0002)	1.10686	0.78880
QY	5	1.000 (± 0.126)	0.0031 (±0.0006)	0.40617	-0.71434
WZ	12	0.987 (± 0.035)	0.0022 (±0.0004)	-1.15138	-6.16071***
YF	2	0.485 (± 0.106)	0.0004 (±0.0001)	1.35640	2.32787
YN	5	0.782 (± 0.107)	0.0011 (±0.0004)	-1.13653	0.36244
SL	9	0.909 (± 0.079)	0.0020 (±0.0004)	-0.32946	-2.27867
DA	1	NA	NA	NA	NA
SG	2	NA	NA	NA	NA
PL	1	NA	NA	NA	NA
WX	2	NA	NA	NA	NA
JM	4	NA	NA	NA	NA
MJ	1	NA	NA	NA	NA
HL	1	NA	NA	NA	NA
总计 Total	52	0.912 (± 0.012)	0.0023 (±0.0001)	-0.91788	-24.88587***

群体 Population	单倍型数 Number of haplotype	单倍型多样性 Haplotype diversity	核苷酸多样性 Nucleotide diversity	中性检测 Neutrality tests
群体 Population	单倍型数 Number of haplotype	单倍型多样性 Haplotype diversity	核苷酸多样性 Nucleotide diversity	Tajima’s D	Fu’s Fs
BS	7	0.383 (± 0.107)	0.0002 (±0.0001)	-1.75856**	-6.19981***
CJ	4	0.806 (± 0.089)	0.0021 (±0.0003)	1.29983	2.70828
CZ	7	0.879 (± 0.058)	0.0009 (±0.0001)	0.01278	-1.77070
GP	10	0.923 (± 0.060)	0.0011 (±0.0001)	-0.27622	-5.21979***
GZ	10	0.917 (± 0.049)	0.0013 (±0.0003)	-1.10830	-3.75174*
HZ	7	0.891 (± 0.074)	0.0014 (±0.0002)	-1.41142	-1.25974
KP	4	0.900 (± 0.161)	0.0019 (±0.0008)	-0.92693	0.35685
LZ	3	0.800 (± 0.164)	0.0026 (±0.0006)	1.25408	2.74649
LC	5	0.893 (± 0.086)	0.0018 (±0.0005)	-0.66317	0.49798
NF	2	0.133 (± 0.112)	0.0001 (±0.0001)	-1.15945	-0.64899
NN	3	0.762 (± 0.115)	0.0006 (±0.0002)	1.10686	0.78880
QY	5	1.000 (± 0.126)	0.0031 (±0.0006)	0.40617	-0.71434
WZ	12	0.987 (± 0.035)	0.0022 (±0.0004)	-1.15138	-6.16071***
YF	2	0.485 (± 0.106)	0.0004 (±0.0001)	1.35640	2.32787
YN	5	0.782 (± 0.107)	0.0011 (±0.0004)	-1.13653	0.36244
SL	9	0.909 (± 0.079)	0.0020 (±0.0004)	-0.32946	-2.27867
DA	1	NA	NA	NA	NA
SG	2	NA	NA	NA	NA
PL	1	NA	NA	NA	NA
WX	2	NA	NA	NA	NA
JM	4	NA	NA	NA	NA
MJ	1	NA	NA	NA	NA
HL	1	NA	NA	NA	NA
总计 Total	52	0.912 (± 0.012)	0.0023 (±0.0001)	-0.91788	-24.88587***

	BS	CJ	CZ	WG	GZ	JH	NF	HZ	KP	ZC	MZ	NN	QY	SL	YF	YN
BS	0.000	***	***	***	***	***	NS	***	***	***	***	***	***	***	***	***
CJ	0.816	0.000	*	*	**	NS	***	NS	NS	NS	NS	NS	NS	NS	*	NS
CZ	0.859	0.160	0.000	NS	***	NS	***	***	NS	*	NS	NS	***	NS	NS	NS
WG	0.838	0.157	0.000	0.000	**	*	***	**	NS	NS	NS	NS	*	*	NS	NS
GZ	0.842	0.260	0.211	0.111	0.000	*	***	NS	*	*	NS	***	***	**	***	***
JH	0.849	0.000	0.237	0.234	0.307	0.000	***	*	NS	NS	NS	NS	NS	NS	*	*
NF	0.000	0.753	0.834	0.802	0.803	0.795	0.000	***	***	***	***	***	***	***	***	***
HZ	0.868	0.264	0.288	0.175	0.025	0.292	0.830	0.000	NS	*	NS	***	**	*	***	***
KP	0.876	0.000	0.021	0.021	0.142	0.000	0.847	0.150	0.000	NS	NS	NS	NS	NS	NS	NS
ZC	0.747	0.000	0.091	0.043	0.103	0.000	0.664	0.119	0.000	0.000	NS	NS	NS	NS	*	NS
MZ	0.765	0.050	0.010	0.000	0.036	0.058	0.691	0.057	0.000	0.000	0.000	NS	*	NS	NS	NS
NN	0.899	0.100	0.083	0.061	0.290	0.192	0.906	0.372	0.136	0.020	0.078	0.000	*	NS	NS	NS
QY	0.841	0.007	0.351	0.344	0.373	0.000	0.779	0.361	0.046	0.062	0.146	0.299	0.000	NS	**	*
SL	0.800	0.000	0.068	0.085	0.168	0.000	0.735	0.185	0.000	0.003	0.000	0.105	0.102	0.000	NS	NS
YF	0.913	0.211	0.000	0.024	0.209	0.324	0.921	0.314	0.053	0.113	0.028	0.227	0.429	0.066	0.000	NS
YN	0.854	0.093	0.000	0.000	0.161	0.146	0.821	0.228	0.000	0.043	0.000	0.107	0.218	0.013	0.000	0.000