Progress on sex determination of dioecious plants

doi:10.17520/biods.2021416

Abstract

Abstract:

Background & Aims: Sexual differentiation of plants, also known as dioecy, is the phenomenon of the different female and male reproductive organs in different species and individuals. Dioecious species of flowering plants evolved independently into multiple phylogenetic branches, with each expressing different sex chromosome status, sex determination regions and genes for each branch. In this review, we will summarize the current direction of sex determination research in angiosperms, and appropriately prospect the direction of future research.

Progress: We summarized the formation process of the plant sex determining gene model and the evolution of plant sex chromosomes after conducting a literature review. Two types of mutation models for plant sex determination have been proposed: the ‘two-mutations’ model clarifies that the evolution of sex determination requires two mutations, leading to male sterility and female sterility respectively, while the ‘single-mutation’ model is a single mutant gene that regulates and determines both male and female development of the plant. The diversity of plant sex chromosomes and sex determination systems provides an excellent opportunity to study the formation mechanism of plant sex-related genes, sex determination regions, and sex chromosome evolution. The evolution of plant chromosomes started with a pair of autosomes producing sex-determining gene mutations, forming the initial sex chromosomes. With different selection pressure between female and male plant individuals, the mutant genes were gradually antagonized, and the recombination inhibition was promoted. Accumulation of repeated elements and inhibition of recombination causes the Hill-Robertson effect, which increases the difference between the two chromosomes and eventually leads to the formation of sex chromosomes. The sex chromosomes of some species gradually evolved from homomorphic chromosomes to heteromorphic chromosomes. In this review, sex-determined regions and genes are sorted out and compared in detail according to currently existing characteristics. At present, most studies on the sex-determining regions and genes of angiosperms are carried out by methods such as genome, transcriptome, and resequencing, and the results are primarily in line with the ‘two-mutations’ or ‘single-mutation’ models. Meanwhile, this review further outlines the application of sex determination research in practical production.

Prospects: We propose four suggestions for future research on sex determination in plants: (1) gradually expanding the sight from gene to the regulatory pathways of research; (2) shifting from a single species to research comparisons of related families and genera; (3) improving and exploring current or new sex-determining gene models or sex-model species; and (4) strengthening the identification technology in actual production research and development efforts.

Key words: dioecious plants, sex determination, sex chromosomes, recombination suppression, ‘two-mutations’, model

Dan Peng, Zhiqiang Wu. Progress on sex determination of dioecious plants[J]. Biodiv Sci, 2022, 30(3): 21416.

Add to citation manager EndNote|Ris|BibTeX

URL: https://www.biodiversity-science.net/EN/10.17520/biods.2021416

https://www.biodiversity-science.net/EN/Y2022/V30/I3/21416

Figures/Tables 3

References 57

[1]	Abraham A, Mathew PM (1962) Cytological studies in the cycads: Sex chromosomes in Cycas. Annals of Botany, 26, 261-266. DOI URL
[2]	Akagi T, Henry IM, Kawai T, Comai L, Tao R (2016) Epigenetic regulation of the sex determination gene MeGI in polyploid persimmon. The Plant Cell, 28, 2905-2915. DOI URL
[3]	Akagi T, Henry IM, Ohtani H, Morimoto T, Beppu K, Kataoka I, Tao R (2018) A Y-encoded suppressor of feminization arose via lineage-specific duplication of a cytokinin response regulator in kiwifruit. The Plant Cell, 30, 780-795. DOI URL
[4]	Akagi T, Henry IM, Tao R, Comai L (2014) Plant genetics. A Y-chromosome-encoded small RNA acts as a sex determinant in persimmons. Science, 346, 646-650. DOI URL
[5]	Akagi T, Pilkington SM, Varkonyi-Gasic E, Henry IM, Sugano SS, Sonoda M, Firl A, McNeilage MA, Douglas MJ, Wang T, Rebstock R, Voogd C, Datson P, Allan AC, Beppu K, Kataoka I, Tao R (2019) Two Y-chromosome-encoded genes determine sex in kiwifruit. Nature Plants, 5, 801-809. DOI URL
[6]	Akagi T, Shirasawa K, Nagasaki H, Hirakawa H, Tao R, Comai L, Henry IM (2020) The persimmon genome reveals clues to the evolution of a lineage-specific sex determination system in plants. PLoS Genetics, 16, e1008566.
[7]	Aryal R, Ming R (2014) Sex determination in flowering plants: Papaya as a model system. Plant Science, 217/218, 56-62. DOI URL
[8]	Bačovský V, Čegan R, Šimoníková D, Hřibová E, Hobza R (2020) The formation of sex chromosomes in Silene latifolia and S. dioica was accompanied by multiple chromosomal rearrangements. Frontiers in Plant Science, 11, 205. DOI PMID
[9]	Cegan R, Marais GA, Kubekova H, Blavet N, Widmer A, Vyskot B, Dolezel J, Safár J, Hobza R (2010) Structure and evolution of Apetala3, a sex-linked gene in Silene latifolia. BMC Plant Biology, 10, 180. DOI URL
[10]	Charlesworth B (1991) The evolution of sex chromosomes. Science, 251, 1030-1033. PMID
[11]	Charlesworth B, Charlesworth D (1978) A model for the evolution of dioecy and gynodioecy. The American Naturalist, 112, 975-997. DOI URL
[12]	Charlesworth D (2012) Plant sex chromosome evolution. Journal of Experimental Botany, 64, 405-420. DOI URL
[13]	Charlesworth D (2013) Evolution of Sex Chromosomes in Plants. In:Encyclopedia of Life Sciences. In: Encyclopedia of Life Sciences. John Wiley & Sons, Ltd: Chichester. https://doi.org/10.1002/9780470015902.a0025144.
[14]	Charlesworth D (2015) Plant contributions to our understanding of sex chromosome evolution. New Phytologist, 208, 52-65. DOI PMID
[15]	Charlesworth D (2016) Plant sex chromosomes. Annual Review of Plant Biology, 67, 397-420. DOI PMID
[16]	Charlesworth D (2019) Young sex chromosomes in plants and animals. New Phytologist, 224, 1095-1107. DOI PMID
[17]	Charlesworth D, Charlesworth B, Marais G (2005) Steps in the evolution of heteromorphic sex chromosomes. Heredity, 95, 118-128. DOI PMID
[18]	Delph LF, Arntz AM, Scotti-Saintagne C, Scotti I (2010) The genomic architecture of sexual dimorphism in the dioecious plant Silene latifolia. Evolution, 64, 2873-2886.
[19]	Fu L, Zheng YH, Wu MY, Han FG, Gu YH, Zhang HW (2019) A Method for Identifying the Sex of A Dioecious Plant. CN109655519A. Released date: 20190419. (in Chinese)
	[ 傅力, 郑玉红, 吴梦瑶, 韩福贵, 顾永华, 张怀伟 (2019) 一种雌雄异株植物的性别鉴定方法. CN109655519A. 发布日期: 20190419. ]
[20]	Harkess A, Huang K, van der Hulst R, Tissen B, Caplan JL, Koppula A, Batish M, Meyers BC, Leebens-Mack J (2020) Sex determination by two Y-linked genes in garden Asparagus. The Plant Cell, 32, 1790-1796. DOI PMID
[21]	Harkess A, Zhou J, Xu C, Bowers JE, van der Hulst R, Ayyampalayam S, Mercati F, Riccardi P, McKain MR, Kakrana A, Tang H, Ray J, Groenendijk J, Arikit S, Mathioni SM, Nakano M, Shan H, Telgmann-Rauber A, Kanno A, Yue Z, Chen H, Li W, Chen Y, Xu X, Zhang Y, Luo S, Chen H, Gao J, Mao Z, Pires JC, Luo M, Kudrna D, Wing RA, Meyers BC, Yi K, Kong H, Lavrijsen P, Sunseri F, Falavigna A, Ye Y, Leebens-Mack JH, Chen G (2017) The asparagus genome sheds light on the origin and evolution of a young Y chromosome. Nature Communications, 8, 1279. DOI PMID
[22]	Hormaza JI, Dollo L, Polito VS (1994) Identification of a RAPD marker linked to sex determination in Pistacia vera using bulked segregant analysis. Theoretical and Applied Genetics, 89, 9-13. DOI PMID
[23]	Janick J, Stevenson EC (1954) A genetic study of the heterogametic nature of the staminate plant in spinach. Journal of the American Society for Horticultural Science, 63, 444-446.
[24]	Jia HM, Jia HJ, Cai QL, Wang Y, Zhao HB, Yang WF, Wang GY, Li YH, Zhan DL, Shen YT, Niu QF, Chang L, Qiu J, Zhao L, Xie HB, Fu WY, Jin J, Li XW, Jiao Y, Zhou CC, Tu T, Chai CY, Gao JL, Fan LJ, van de Weg E, Wang JY, Gao ZS (2018) The red bayberry genome and genetic basis of sex determination. Plant Biotechnology Journal, 17, 397-409. DOI URL
[25]	Kazama Y, Ishii K, Aonuma W, Ikeda T, Kawamoto H, Koizumi A, Filatov DA, Chibalina M, Bergero R, Charlesworth D, Abe T, Kawano S (2016) A new physical mapping approach refines the sex-determining gene positions on the Silene latifolia Y-chromosome. Scientific Reports, 6, 18917. DOI URL
[26]	Li GL, Lin BN, Shen DX (1993) Sex identification of horticultural dioecious plants by phenolics analysis. Acta Horticulturae Sinica, 20, 397-398. (in Chinese)
	[ 李国梁, 林伯年, 沈德绪 (1993) 酚类物质在鉴别园艺雌雄性植物中的应用研究. 园艺学报, 20, 397-398.]
[27]	Li W, Wu HT, Li XP, Chen YN, Yin TM (2020) Fine mapping of the sex locus in Salix triandra confirms a consistent sex determination mechanism in genus Salix. Horticulture Research, 7, 64. DOI URL
[28]	Liao QG, Du R, Gou JB, Guo LJ, Shen H, Liu HL, Nguyen JK, Ming R, Yin TM, Huang SW, Yan JB (2020) The genomic architecture of the sex-determining region and sex-related metabolic variation in Ginkgo biloba. The Plant Journal, 104, 1399-1409. DOI URL
[29]	Liu Z, Moore PH, Ma H, Ackerman CM, Ragiba M, Yu Q, Pearl HM, Kim MS, Charlton JW, Stiles JI, Zee FT, Paterson AH, Ming R (2004) A primitive Y chromosome in papaya marks incipient sex chromosome evolution. Nature, 427, 348-352. DOI URL
[30]	Lorenzo JLR, Hobza R, Vyskot B (2018) DNA methylation and genetic degeneration of the Y chromosome in the dioecious plant Silene latifolia. BMC Genomics, 19, 540. DOI URL
[31]	Massonnet M, Cochetel N, Minio A, Vondras AM, Lin J, Muyle A, Garcia JF, Zhou Y, Delledonne M, Riaz S, Figueroa-Balderas R, Gaut BS, Cantu D (2020) The genetic basis of sex determination in grapes. Nature Communications, 11, 2902. DOI PMID
[32]	Ming R, Bendahmane A, Renner SS (2011) Sex chromosomes in land plants. Annual Review of Plant Biology, 62, 485-514. DOI PMID
[33]	Ming R, Yu QY, Moore PH (2007) Sex determination in papaya. Seminars in Cell and Developmental Biology, 18(3), 401-408. PMID
[34]	Müller NA, Kersten B, Leite Montalvão AP, Mähler N, Bernhardsson C, Bräutigam K, Carracedo Lorenzo Z, Hoenicka H, Kumar V, Mader M, Pakull B, Robinson KM, Sabatti M, Vettori C, Ingvarsson PK, Cronk Q, Street NR, Fladung M (2020) A single gene underlies the dynamic evolution of poplar sex determination. Nature Plants, 6, 630-637. DOI PMID
[35]	Picq S, Santoni S, Lacombe T, Latreille M, Weber A, Ardisson M, Ivorra S, Maghradze D, Arroyo-Garcia R, Chatelet P, This P, Terral JF, Bacilieri R (2014) A small XY chromosomal region explains sex determination in wild dioecious V. vinifera and the reversal to hermaphroditism in domesticated grapevines. BMC Plant Biology, 14, 229. DOI URL
[36]	Prentout D, Razumova O, Rhoné B, Badouin H, Henri H, Feng C, Käfer J, Karlov G, Marais GAB (2020) An efficient RNA-seq-based segregation analysis identifies the sex chromosomes of Cannabis sativa. Genome Research, 30, 164-172. DOI PMID
[37]	Qian W, Fan GY, Liu DD, Zhang HL, Wang XW, Wu J, Xu ZS (2017) Construction of a high-density genetic map and the X/Y sex-determining gene mapping in spinach based on large-scale markers developed by specific-locus amplified fragment sequencing (SLAF-seq). BMC Genomics, 18, 276.
[38]	Renner SS, Ricklefs RE (1995) Dioecy and its correlates in the flowering plants. American Journal of Botany, 82, 596-606. DOI URL
[39]	Riaz S, Krivanek AF, Xu K, Walker MA (2006) Refined mapping of the Pierce’s disease resistance locus, PdR1, and sex on an extended genetic map of Vitis rupestris × V. arizonica. Theoretical and Applied Genetics, 113, 1317-1329. PMID
[40]	She HB, Xu ZS, Zhang HL, Li GL, Wu J, Wang XW, Li Y, Liu ZY, Qian W (2021) Identification of a male-specific region (MSR) in Spinacia oleracea. Horticultural Plant Journal, 7, 341-346. DOI URL
[41]	Sondur SN, Manshardt RM, Stiles JI (1996) A genetic linkage map of papaya based on randomly amplified polymorphic DNA markers. Theoretical and Applied Genetics, 93, 547-553. DOI PMID
[42]	Spigler RB, Lewers KS, Main DS, Ashman TL (2008) Genetic mapping of sex determination in a wild strawberry, Fragaria virginiana, reveals earliest form of sex chromosome. Heredity, 101, 507-517. DOI PMID
[43]	Storey WB (1953) Genetics of the papaya. Journal of Heredity, 44, 70-78. DOI URL
[44]	Tao YS, Liao YM, Li YX, Wang BX, Liao XL, Ye XD, Chen JS (2013) Morphological characteristics and physiological-biochemical indexes of male and female Cercidiphyllum japonicum. Journal of Northeast Forestry University, 41(3), 18-19, 39. (in Chinese with English abstract)
	[ 陶应时, 廖咏梅, 黎云祥, 王碧霞, 廖兴利, 叶兴东, 陈劲松 (2013) 连香树雌雄株叶片形态及生理生化指标比较. 东北林业大学学报, 41(3), 18-19, 39.]
[45]	Tennessen JA, Wei N, Straub SCK, Govindarajulu R, Liston A, Ashman TL (2018) Repeated translocation of a gene cassette drives sex-chromosome turnover in strawberries. PLoS Biology, 16, e2006062. DOI URL
[46]	Villarreal JC, Renner SS (2013) Correlates of monoicy and dioicy in hornworts, the apparent sister group to vascular plants. BMC Evolutionary Biology, 13, 239. DOI PMID
[47]	Walas L, Mandryk W, Thomas PA, Tyrala-Wierucka Z, Iszkulo G (2018) Sexual systems in gymnosperms: A review. Basic and Applied Ecology, 31, 1-9. DOI URL
[48]	Wang BP, Cheng XJ, Dai WS, Yang FF (1999) Seasonal variation of endogenous hormones and nucleicacids in female and male plants of Ginko biloba. Journal of Zhejiang Forestry College, 16, 114-118. (in Chinese with English abstract)
	[ 王白坡, 程晓建, 戴文圣, 杨飞峰 (1999) 银杏雌雄株内源激素和核酸的变化. 浙江林学院学报, 16, 114-118.]
[49]	Wang JP, Na JK, Yu QY, Gschwend AR, Han J, Zeng FC, Aryal R, VanBuren R, Murray JE, Zhang WL, Navajas-Pérez R, Feltus FA, Lemke C, Tong EJ, Chen CX, Wai CM, Singh R, Wang ML, Min XJ, Alam M, Charlesworth D, Moore PH, Jiang JM, Paterson AH, Ming R (2012) Sequencing papaya X and Y^h chromosomes reveals molecular basis of incipient sex chromosome evolution. Proceedings of the National Academy of Sciences, USA, 109, 13710-13715.
[50]	Werren JH, Beukeboom LW (1998) Sex determination, sex ratios, and genetic conflict. Annual Review of Ecology and Systematics, 29, 233-261. DOI URL
[51]	Westergaard M (1958) The mechanism of sex determination in dioecious flowering plants. Advances in Genetics, 9, 217-281.
[52]	Xue LJ, Wu HT, Chen YN, Li XP, Hou J, Lu J, Wei SY, Dai XG, Matthew S. Olson, Liu JQ, Wang MX, Charlesworth D, Yin TM (2020) Two antagonistic effect genes mediate separation of sexes in a fully dioecious plant. bioRxiv: 993022. https://www.biorxiv.org/content/10.1101/2020.03.15.993022v1 . (accessed on 2020-08-10)
[53]	Yamato KT, Ishizaki K, Fujisawa M, Okada S, Nakayama S, Fujishita M, Bando H, Yodoya K, Hayashi K, Bando T, Hasumi A, Nishio T, Sakata R, Yamamoto M, Yamaki A, Kajikawa M, Yamano T, Nishide T, Choi SH, Shimizu-Ueda Y, Hanajiri T, Sakaida M, Kono K, Takenaka M, Yamaoka S, Kuriyama C, Kohzu Y, Nishida H, Brennicke A, Shin-i T, Kohara Y, Kohchi T, Fukuzawa H, Ohyama K (2007) Gene organization of the liverwort Y chromosome reveals distinct sex chromosome evolution in a haploid system. Proceedings of the National Academy of Sciences, USA, 104, 6472-6477.
[54]	Yang WL, Wang DY, Li YL, Zhang ZY, Tong SF, Li MM, Zhang X, Zhang L, Ren LW, Ma XZ, Zhou R, Sanderson BJ, Keefover-Ring K, Yin TM, Smart LB, Liu JQ, DiFazio SP, Olson M, Ma T (2021) A general model to explain repeated turnovers of sex determination in the Salicaceae. Molecular Biology and Evolution, 38, 968-980. DOI URL
[55]	Zhang H, Zhang R, Yang XW, Gu KJ, Chen WB, Chang Y, Xu QW, Liu Q, Qin YT, Hong XN, Seim I, Lin HY, Li WH, Tian JF, Li SS, Liu JN, Su XS, Wang CY, Zhang FM, Ge S, Fu CX, Lee SMY, Xia YJ, Wang J, Yang HM, Fan GY, Xu X, Zhao YP, Xin (2019) Recent origin of an XX/XY sex-determination system in the ancient plant lineage Ginkgo biloba. bioRxiv: 517946. https://www.biorxiv.org/co ntent/10.1101/517946v1 . (accessed on 2020-08-24)
[56]	Zhou R, Macaya-Sanz D, Carlson CH, Schmutz J, Jenkins JW, Kudrna D, Sharma A, Sandor L, Shu SQ, Barry K, Tuskan GA, Ma T, Liu JQ, Olson M, Smart LB, DiFazio SP (2020) A willow sex chromosome reveals convergent evolution of complex palindromic repeats. Genome Biology, 21, 38. DOI PMID
[57]	Zluvova J, Nicolas M, Berger A, Negrutiu I, Monéger F (2006) Premature arrest of the male flower meristem precedes sexual dimorphism in the dioecious plant Silene latifolia. Proceedings of the National Academy of Sciences, USA, 103, 18854-18859.

类群 Taxon	物种 Species	性别决定系统 Sex determination system	性别决定区域或基因 Sex-linked region or genes	同源基因或家族 Ortholog gene or family	参考文献 Reference
苔藓植物 Bryophyte	地钱 Marchantia polymorpha	XY	14个雄性特异性基因 14 male-specific genes	-	Yamato et al, 2007
裸子植物 Gymnosperm	银杏 Ginkgo biloba	ZW	GbMADS18, Gb_15883, Gb_15884, Gb_15885, Gb_15886, Gb_28587	MADS-box (GbMADS18), RR12 (Gb_15883), RR2 (Gb_15884), ELF6 (Gb_15885), AtBAT1 (Gb_15886), AGL8 (Gb_28587)	Zhang et al, 2019; Liao et al, 2020
被子植物 Angiosperm	番木瓜 Carica papaya	XY	MSY4-5Mb, HSY8.1 Mb, XSY3.5 Mb	-	Liu et al, 2004; Wang et al, 2012
	菠菜 Spinacia oleracea	XY	4号连锁群 LG4 (66.98-69.72 cM and 75.48-92.96 cM)	-	Qian et al, 2017; She et al, 2021
	杨梅 Myrica rubra	ZW	59 kb 8号染色体雌性特异性片段 59 kb female-specific region on chromosome 8	-	Jia et al, 2019
	大麻 Cannabis sativa	XY	性染色体 Sex chromosomes	-	Prentout et al, 2020
	蝇子草 Silene latifolia	XY	SlAP3, SlSTM, SlCUC	AP3 (SlAP3), STM (SlSTM), CUC1/CUC2 (SlCUC)	Zluvova et al, 2006; Cegan et al, 2010
	草莓 Fragaria virginiana	ZW	GMEW, RPP0W	GDP-mannose 3,5-epimerase 2 (GMEW), 60S acidic ribosomal protein P0 (RPP0W)	Charlesworth, 2013; Tennessen et al, 2018
	葡萄 Vitis vinifera	XY	VviINP1, VviYABBY3	INP1 (VviINP1), YAB1 (VviYABBY3)	Massonnet et al, 2020
	君迁子 Diospyros lotus	XY	MeGI, OGI	HB40 (MeGI)	Akagi et al, 2020; Xue et al, 2020
	芦笋 Asparagus officinalis	XY	SOFF, aspTDF1	DUF247 (SOFF), TDF1 (aspTDF1)	Harkess et al, 2017, 2020
	猕猴桃 Actinidia chinensis	XY	SyGl, FrBy	ARR24 (SyGl), FAS1 (FrBy)	Akagi et al, 2018, 2019
	杨树 Populus deltoides, P. tremula, P. alba	XY, ZW	FERR-R, FERR, MmS, ARR17	ARR17	Müller et al, 2020; Xue et al, 2020
	柳树 Salix purpurea, S. triandra	ZW	RR	RR9/ARR17	Li et al, 2020; Zhou et al, 2020

类群 Taxon	物种 Species	性别决定系统 Sex determination system	性别决定区域或基因 Sex-linked region or genes	同源基因或家族 Ortholog gene or family	参考文献 Reference
苔藓植物 Bryophyte	地钱 Marchantia polymorpha	XY	14个雄性特异性基因 14 male-specific genes	-	Yamato et al, 2007
裸子植物 Gymnosperm	银杏 Ginkgo biloba	ZW	GbMADS18, Gb_15883, Gb_15884, Gb_15885, Gb_15886, Gb_28587	MADS-box (GbMADS18), RR12 (Gb_15883), RR2 (Gb_15884), ELF6 (Gb_15885), AtBAT1 (Gb_15886), AGL8 (Gb_28587)	Zhang et al, 2019; Liao et al, 2020
被子植物 Angiosperm	番木瓜 Carica papaya	XY	MSY4-5Mb, HSY8.1 Mb, XSY3.5 Mb	-	Liu et al, 2004; Wang et al, 2012
	菠菜 Spinacia oleracea	XY	4号连锁群 LG4 (66.98-69.72 cM and 75.48-92.96 cM)	-	Qian et al, 2017; She et al, 2021
	杨梅 Myrica rubra	ZW	59 kb 8号染色体雌性特异性片段 59 kb female-specific region on chromosome 8	-	Jia et al, 2019
	大麻 Cannabis sativa	XY	性染色体 Sex chromosomes	-	Prentout et al, 2020
	蝇子草 Silene latifolia	XY	SlAP3, SlSTM, SlCUC	AP3 (SlAP3), STM (SlSTM), CUC1/CUC2 (SlCUC)	Zluvova et al, 2006; Cegan et al, 2010
	草莓 Fragaria virginiana	ZW	GMEW, RPP0W	GDP-mannose 3,5-epimerase 2 (GMEW), 60S acidic ribosomal protein P0 (RPP0W)	Charlesworth, 2013; Tennessen et al, 2018
	葡萄 Vitis vinifera	XY	VviINP1, VviYABBY3	INP1 (VviINP1), YAB1 (VviYABBY3)	Massonnet et al, 2020
	君迁子 Diospyros lotus	XY	MeGI, OGI	HB40 (MeGI)	Akagi et al, 2020; Xue et al, 2020
	芦笋 Asparagus officinalis	XY	SOFF, aspTDF1	DUF247 (SOFF), TDF1 (aspTDF1)	Harkess et al, 2017, 2020
	猕猴桃 Actinidia chinensis	XY	SyGl, FrBy	ARR24 (SyGl), FAS1 (FrBy)	Akagi et al, 2018, 2019
	杨树 Populus deltoides, P. tremula, P. alba	XY, ZW	FERR-R, FERR, MmS, ARR17	ARR17	Müller et al, 2020; Xue et al, 2020
	柳树 Salix purpurea, S. triandra	ZW	RR	RR9/ARR17	Li et al, 2020; Zhou et al, 2020