Back Article

Ku CZ, Robertson KR. 2003. Flora of China. Beijing: Science Press. pp. 46−434 www.iplant.cn/foc/vol/9

Jian H, Zhao L, Zhang H, Ma C, Wang Q, et al. 2022. Phylogeography and population genetics of Rosa chinensis var. spontanea and R. lucidissima complex, the important ancestor of modern roses. Frontiers in Plant Science 13:851396

Liorzou M, Pernet A, Li S, Chastellier A, Thouroude T, et al. 2016. Nineteenth century French rose (Rosa sp.) germplasm shows a shift over time from a European to an Asian genetic background. Journal of Experimental Botany 67:4711−4725

Zhu ZM, Gao XF, Fougère-Danezan M. 2015. Phylogeny of Rosa sections Chinenses and Synstylae (Rosaceae) based on chloroplast and nuclear markers. Molecular Phylogenetics and Evolution 87:50−64

Raymond O, Gouzy J, Just J, Badouin H, Verdenaud M, et al. 2018. The Rosa genome provides new insights into the domestication of modern roses. Nature Genetics 50:772−777

Yu TT. 1985. Flora Reipublicae Popularis Sinicae. Vol. 37. Beijing: Science Press. 520 pp. (in Chinese) www.nhbs.com/3/series/flora-republicae-popularis-sinicae?qtview=56742

Ma Y. 1992. Systematic study on the breeding of Rejuvenation Rose Group(Rj.). Thesis. Beijing Forestry University, Beijing, China. pp. 1−14 (in Chinese) https://d.wanfangdata.com.cn/thesis/Y152388

Bao Z. 1993. Preliminary study on wild Rosa resources in the three north regions and the lagged fluorescence and ultra weak luminescence dynamics of several plants. Thesis. Beijing Forestry University, China. pp. 5−11 (in Chinese) https://d.wanfangdata.com.cn/thesis/Y173937

Liu S, Cong Z. 2000. Xinjiang Rosa. Urumqi: Xinjiang Science, Technology and Health Press. pp. 3−12 (in Chinese) https://opac.bjfu.edu.cn/#/searchList/bookDetails/98497

Wang XC. 2001. Germplasm resources of Rosa in Gansu Province and their development and utilization. Forest By-Product and Speciality in China 3:44−45 (in Chinese)

Cheng ZW, Shu YM. 2005. Rosa plants resources in Anhui Province and its exploitation and development. Resource Development & Market 21:538−539,490 (in Chinese)

Wang KL, Tang QH, Liu QC, Fang HW, Liu QH. 2007. Investigation and landscape application of Rosa resources in Shandong Province. Journal of Anhui Agricultural Sciences 35:1988−1989 (in Chinese)

Tang K. 2009. Research on Rosa germplasm resources in Yunnan Province. Thesis. Yunnan University, China. pp. 18−22 (in Chinese) https://d.wanfangdata.com.cn/thesis/Y1654347

Zhang Q. 2011. The Germplasm Resources of Ornamental Plants in Ningxia, China. Beijing: China Forestry Publishing House. 299 pp. (in Chinese) www.hceis.com/home/book_view.aspx?id=9817

Zhang Q. 2014. The Germplasm Resources of Ornamental Plants in Tibet, China. Beijing: China Forestry Publishing House. 386 pp. (in Chinese) https://opac.bjfu.edu.cn/#/searchList/bookDetails/366498

Zhang Q. 2021. The Germplasm Resources of Ornamental Plants in Xinjiang, China. Beijing: China Forestry Publishing House. 442 pp. (in Chinese) www.hceis.com/home/book_view.aspx?id=14771

Wylie AP. 1954. The history of garden roses. Journal of the Royal Horticultural Society 79:8−24

Cairns T. 2000. Modern roses XI: the world encyclopedia of roses. 1^st Edition. San Diego: Academic Press. 638 pp. https://uhawaii-manoa.primo.exlibrisgroup.com/discovery/fulldisplay/alma9920758974605682/01UHAWAII_MANOA:MANOA

Bruneau A, Starr JR, Joly S. 2007. Phylogenetic relationships in the genus Rosa: new evidence from chloroplast DNA sequences and an appraisal of current knowledge. Systematic Botany 32:366−378

Rehder A. 1947. Manual of cultivated trees and shrubs. New York: The MacMillan Company. pp. 426−451 www.cabidigitallibrary.org/doi/full/10.5555/19480300764

Malécot V, Debray K. 2023. Towards a reclassification of the genus Rosa. Acta Horticulturae 1368:347−350

Jian HY, Tang KX, Sun H. 2015. Phylogeography of Rosa soulieana (Rosaceae) in the Hengduan Mountains: refugia and ‘melting’ pots in the Quaternary climate oscillations. Plant Systematics and Evolution 301:1819−1830

Luo L, Yu C, Guo X, Pan H, Zhang Q. 2018. Morphological Variation and Palynomorphology of Rosa laxa in Xinjiang, China. Journal of the American Society for Horticultural Science 143:409−417

Wang S, Zhu Z. 2022. Relationships between species richness patterns of Rosa L. and environmental factors in China. Acta Ecologica Sinica 42:209−219 (in Chinese)

Li SQ, Zhang C, Gao XF. 2023. Geographic isolation and climatic heterogeneity drive population differentiation of Rosa chinensis var. spontanea complex. Plant Biology 25:620−630

Cheng B, Zhao K, Zhou M, Bourke PM, Zhou L, et al. 2025. Phenotypic and genomic signatures across wild Rosa species open new horizons for modern rose breeding. Nature Plants 11:775−789

Stein A, Gerstner K, Kreft H. 2014. Environmental heterogeneity as a universal driver of species richness across taxa, biomes and spatial scales. Ecology Letters 17:866−880

Shrestha N, Su X, Xu X, Wang Z. 2018. The drivers of high Rhododendron diversity in south-west China: does seasonality matter? Journal of Biogeography 45:438−447

Zou DT, Wang QG, Luo A, Wang ZH. 2019. Species richness patterns and resource plant conservation assessments of Rosaceae in China. Chinese Journal of Plant Ecology 43:1−15 (in Chinese)

Gaston KJ. 2000. Global patterns in biodiversity. Nature 405:220−227

Rao M, Steinbauer MJ, Xiang X, Zhang M, Mi X, et al. 2018. Environmental and evolutionary drivers of diversity patterns in the tea family (Theaceae s.s.) across China. Ecology and Evolution 8:11663−11676

Su T, Huang YJ, Meng J, Zhang ST, Huang J, et al. 2016. A Miocene leaf fossil record of Rosa (R. fortuita n. sp.) from its modern diversity center in SW China. Palaeoworld 25:104−115

Luo L, Yang Y, Zhang Q. 2024. Genus Rosa L. in China. Beijing: China Forestry Publishing House. 534 pp. (in Chinese) www.hceis.com/home/book_view.aspx?id=3727

Hung LY, Wang JC. 2022. A revision of Rosa transmorrisonensis Hayata and allied species in Taiwan. Taiwania 67:484−496

Ullah F, Gao YD, Zaman W, Gao XF. 2022. Pollen morphology of Rosa sericea complex and their taxonomic contribution. Diversity-Basel 14:705

Zhou LH, Wei ZX, Wu ZY. 1999. Pollen morphology of Rosoideae (Rosaceae) of China. Acta Botanica Yunnanica 21:455−460,535+536 (in Chinese)

Fang Q, Tian M, Zhang T, Wang QG, Yan HJ, et al. 2020. Karyotype analysis of Rosa praelucens and its closely related congeneric species based on FISH. Acta Horticulturae Sinica 47:503−516 (in Chinese)

Qiu X, Zhang H, Wang Q, Jian H, Yan H, et al. 2012. Phylogenetic relationships of wild roses in China based on nrDNA and matK data. Scientia Horticulturae 140:45−51

Jan CH, Byrne DH, Manhart J, Wilson H. 1999. Rose germplasm analysis with RAPD markers. HortScience 34:341−345

Koopman WJM, Wissemann V, De Cock K, Van Huylenbroeck J, De Riek J, et al. 2008. AFLP markers as a tool to reconstruct complex relationships: a case study in Rosa (Rosaceae). American Journal of Botany 95:353−366

Akond M, Jin S, Wang X. 2012. Molecular characterization of selected wild species and miniature roses based on SSR markers. Scientia Horticulturae 147:89−97

Lu M, Zhang H, An H, Zhou W. 2020. Genetic variation and population structure of Rosa roxburghii by EST-based and genomic SSR markers. Pakistan Journal of Botany 52:1315−1322

Jiang L, Zang D. 2018. Analysis of genetic relationships in Rosa rugosa using conserved DNA-derived polymorphism markers. Biotechnology & Biotechnological Equipment 32:88−94

Zhang C, Li SQ, Xie HH, Liu JQ, Gao XF. 2022. Comparative plastid genome analyses of Rosa: insights into the phylogeny and gene divergence. Tree Genetics & Genomes 18:20

Jian HY, Zhang YH, Yan HJ, Qiu XQ, Wang QG, et al. 2018. The complete chloroplast genome of a key ancestor of modern roses, Rosa chinensis var. spontanea, and a comparison with congeneric species. Molecules 23:389

Lin W, Huang J, Xue M, Wang X, Wang C. 2019. Characterization of the complete chloroplast genome of Chinese rose, Rosa chinensis (Rosaceae: Rosa). Mitochondrial DNA Part B 4:2984−2985

Debray K, Le Paslier MC, Bérard A, Thouroude T, Michel G, et al. 2022. Unveiling the patterns of reticulated evolutionary processes with phylogenomics: hybridization and polyploidy in the genus Rosa. Systematic Biology 71:547−569

Nakamura N, Hirakawa H, Sato S, Otagaki S, Matsumoto S, et al. 2018. Genome structure of Rosa multiflora, a wild ancestor of cultivated roses. DNA Research 25:113−121

Zang F, Ma Y, Tu X, Huang P, Wu Q, et al. 2021. A high-quality chromosome-level genome of wild Rosa rugosa. DNA Research 28:dsab017

Zhang Z, Yang T, Liu Y, Wu S, Sun H, et al. 2024. Haplotype-resolved genome assembly and resequencing provide insights into the origin and breeding of modern rose. Nature Plants 10:1659−1671

Zhou L, Wu S, Chen Y, Huang R, Cheng B, et al. 2024. Multi-omics analyzes of Rosa gigantea illuminate tea scent biosynthesis and release mechanisms. Nature Communications 15:8469

Zong D, Liu H, Gan P, Ma S, Liang H, et al. 2024. Chromosomal-scale genomes of two Rosa species provide insights into genome evolution and ascorbate accumulation. The Plant Journal 117:1264−1280

Wang S. 2021. The evolutionary history and taxonomyof Rosa brunonii complex. Thesis. Yunnan University, China. pp. 50−54 (in Chinese) doi: 10.27456/d.cnki.gyndu.2021.001282

Wissemann V, Ritz CM. 2005. The genus Rosa (Rosoideae, Rosaceae) revisited: molecular analysis of nrITS-1 and atpB-rbcL intergenic spacer (IGS) versus conventional taxonomy. Botanical Journal of the Linnean Society 147:275−290

Jeon JH, Maki M, Chiang YC, Kim SC. 2025. Inferring complex evolutionary history of the closely related East Asian wild roses in Rosa sect. Synstylae (Rosaceae) based on genomic evidence from conserved orthologues. Annals of Botany 135:417−436

Joly S, Bruneau A. 2007. Delimiting species boundaries in Rosa sect. Cinnamomeae (Rosaceae) in eastern North America. Systematic Botany 32:819−836

Zhang C, Li SQ, Zhu ZM, Li LY, Wu P, et al. 2025. Phylogeny-based morphological evolution and species complex circumscription in Rosa sections Synstylae and Chinenses (Rosaceae), with description of one new species. Botanical Journal of the Linnean Society 211:163−189

Chen F, Su L, Hu S, Xue JY, Liu H, et al. 2021. A chromosome-level genome assembly of rugged rose (Rosa rugosa) provides insights into its evolution, ecology, and floral characteristics. Horticulture Research 8:141

Jayakodi M, Padmarasu S, Haberer G, Bonthala VS, Gundlach H, et al. 2020. The barley pan-genome reveals the hidden legacy of mutation breeding. Nature 588:284−289

Shi J, Tian Z, Lai J, Huang X. 2023. Plant pan-genomics and its applications. Molecular Plant 16:168−186

Richards EJ. 2006. Inherited epigenetic variation — revisiting soft inheritance. Nature Reviews Genetics 7:395−401

Liu C, Wang G, Wang H, Xia T, Zhang S, et al. 2015. Phylogenetic relationships in the genus Rosa revisited based on rpl16, trnL-F, and atpB-rbcL sequences. HortScience 50:1618−1624

Li SQ, Zhang C, Gao XF. 2017. Estimation of nuclear DNA content of 17 Chinese wild rose species by flow cytometry. Plant Science Journal 35:558−565 (in Chinese)

Tan SM, Yung PYM, Hutchinson PE, Xie C, Teo GH, et al. 2019. Primer-free FISH probes from metagenomics/metatranscriptomics data permit the study of uncharacterised taxa in complex microbial communities. npj Biofilms and Microbiomes 5:17

Lu D, Zhang Y, Zhang L, Wang H, Weng W, et al. 2021. Methods of privacy-preserving genomic sequencing data alignments. Briefings in Bioinformatics 22:bbab151

Yuan Y, Feng Y, Wang J, Ullah F, Yuan M, et al. 2025. Integrative taxonomy for species delimitation: a case study in two widely accepted yet morphologically confounding Rosa species within sect. Pimpinellifoliae (Rosaceae). Molecular Ecology 34:e17779

Zhang R, Liu S, Liu Y, Wei P, Xiang N, et al. 2025. Comparative analysis of the organelle genomes of seven Rosa species (Rosaceae): insights into structural variation and phylogenetic position. Frontiers in Plant Science 16:1584289

Tang Z, Liang Z, Deng H, Li L, Ru J, et al. 2026. Integrative morphological and genomic analyses reveal diversity, reticulate evolution, and adaptation in diploid and tetraploid Rosa species from Xinjiang. Molecular Phylogenetics and Evolution 218:108555

Yu J, Chen Q, Yuan L, Feng S, Huang M, et al. 2025. Phylogenomic and super-pangenome analyses unveil the genetic landscape of tomato evolution and domestication. Plant Biotechnology Journal. 23:3783−3797

Matsumoto S, Kouchi M, Yabuki J, Kusunoki M, Ueda Y, et al. 1998. Phylogenetic analyses of the genus Rosa using the matK sequence: molecular evidence for the narrow genetic background of modern roses. Scientia Horticulturae 77:73−82

Wu S, Ueda Y, He H, Nishihara S, Matsumoto S. 2000. Phylogenetic analysis of Japanese Rosa species using matK sequences. Breeding Science 50:275−281

Fougère-Danezan M, Joly S, Bruneau A, Gao XF, Zhang LB. 2015. Phylogeny and biogeography of wild roses with specific attention to polyploids. Annals of Botany 115:275−291

Wei XM. 2008. Studies on the systematics of Rosa Sect. pimpinellifoliae DC. ex Ser. in China. Ph.D. Dissertation. Chengdu Institute of Biology, Chinese Academy of Sciences, Chengdu, China. pp. 60−61 (in Chinese) https://d.wanfangdata.com.cn/thesis/Y1614449

Cao YL, He YH, Li CL. 1996. Vitamin contents in the hips of 38 species of Rosa and their relation to division of sections. Acta Botanica Sinica 38:822−827 (in Chinese)

Deng HN. 2016. Molecular phylogeny and speciation of Rosa Section Microphyllae (Rosaceae). Thesis. Southwest University, China. pp. 41−47 (in Chinese)

Wang KJ. 2018. The phylogenetic position and hybrid origination of Rosa praelucens Byhouwer and the molecular phylogeny of Genus Rosa L. Thesis. Yunnan University, China. pp. 39−47 (in Chinese)

Yang X, Su Y, Huang S, Hou Q, Wei P, et al. 2024. Comparative population genomics reveals convergent and divergent selection in the apricot–peach–plum–mei complex. Horticulture Research 11:uhae109

Dayrat B. 2005. Towards integrative taxonomy. Biological Journal of the Linnean Society 85:407−415

Padial JM, Miralles A, De la Riva I, Vences M. 2010. The integrative future of taxonomy. Frontiers in Zoology 7:16

Maltsev Y, Erst A. 2023. Recent advances in the integrative taxonomy of plants. Plants 12:4097

Li YC, Zhong DL, Rao GY, Wen J, Ren Y, et al. 2018. Gone with the trees: phylogeography of Rhodiola sect. Trifida (Crassulaceae) reveals multiple refugia on the Qinghai-Tibetan Plateau. Molecular Phylogenetics and Evolution 121:110−120

Batista JAN, Castro C, Sambin A, Cruz-Lustre G, Pansarin ER. 2023. Clarifying the identity of the Cleistes rosea complex (Orchidaceae) based on integrative taxonomy. Systematics and Biodiversity 21:2207575

Deng T, Luo L, Yu C, Zhang QX, Liu XS, et al. 2022. Rosa tomurensis, a new species of Rosa (Rosaceae) from China. Phytotaxa 556:169−177

Jacobs SJ, Grundler MC, Henriquez CL, Zapata F. 2021. An integrative genomic and phenomic analysis to investigate the nature of plant species in Escallonia (Escalloniaceae). Scientific Reports 11:24013

Erst AS, Mitrenina EY, Krivenko DA, Erst TV, Cheldysheva YV, Gorbenko IV, et al. 2026. A revision of the genus Beesia (Ranunculaceae) as informed through integrative taxonomy, with description of a new species from Sichuan (China). Frontiers in Plant Science 16:1699952

Gao YD, Zhang Y, Gao XF, Zhu ZM. 2015. Pleistocene glaciations, demographic expansion and subsequent isolation promoted morphological heterogeneity: a phylogeographic study of the alpine Rosa sericea complex (Rosaceae). Scientific Reports 5:11698

Tang YW, Luo L, Liu XS, Tian XL, Lyu PF, et al. 2024. Rosa forrestiana var. maculata, a new variety of Rosa (Rosaceae) from Yunnan, China. Phytotaxa 652:293−299

Lyu P, Luo L, Tang Y, Tian X, Yu C, et al. 2023. Rosa yangii (Rosaceae), a new species from China. Kew Bulletin 78:663−671

Zheng LN, Luo L, Tang YW, Yu C, Lyu PF, et al. 2023. Rosa funingensis (Rosaceae), a new species from Yunnan, China. PhytoKeys 229:61−70

Wäldchen J, Mäder P. 2018. Plant species identification using computer vision techniques: a systematic literature review. Archives of Computational Methods in Engineering 25:507−543