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油茶是我国重要的木本油料作物,具有较高的经济价值和生态效益。随着基因组学、转录组学、代谢组学等多组学技术的快速发展,油茶经济性状及相关生物学研究取得显著进展,油茶基因组的破译标志着油茶育种进入基因组育种阶段。首先,梳理了油茶全基因组测序进展,并剖析其基因组的复杂性和多样性;其次,从多组学角度综述油茶生殖生长过程中开花授粉、自交不亲和、果实脱落等关键环节调控机制。同时,总结了油茶油脂及其活性成分(如黄酮类、角鲨烯、茶皂素等)的合成途径及调控网络,并整理出油茶在抵抗干旱、低温、病虫害及营养缺乏等逆境胁迫下的关键基因及功能。旨在为油茶的遗传改良、品质提升及抗逆性育种提供理论依据,以推动多组学技术在木本油料作物育种中的应用。
Abstract:Camellia oleifera is a significant woody oil crop in China, valued for its substantial economic potential and ecological benefits. With the rapid advancement of multi-omics technologies, including genomics, transcriptomics, and metabolomics, considerable progress has been achieved in the study of its economic traits and associated biological mechanisms. The successful decoding of the Camellia oleifera genome signifies that its breeding has entered the genomic breeding era. Firstly, the progress in whole-genome sequencing was reviewed and the complexity and diversity of the genome were analyzed. Secondly, the regulatory mechanisms underlying key reproductive processes, such as flowering and pollination, self-incompatibility, and fruit abscission, from a multi-omics perspective were summarized. Furthermore, the biosynthesis pathways and regulatory networks of Camellia oleifera oil and its bioactive compounds(e.g., flavonoids, squalene, and tea saponins) were outlined. Additionally, key genes and their functions involved in stress resistance against drought, low temperature, pests and diseases, and nutrient deficiency were identified. The objective is to provide a theoretical foundation for the genetic improvement, quality enhancement, and stress-resistant breeding of Camellia oleifera, thereby promoting the application of multi-omics technologies in the breeding of woody oil crops.
[1] 孔庆博,向婷婷,邝雪琨,等.我国西南和东部地区野生油茶及其近缘物种资源调查、收集与保护[J].植物科学学报,2022,40(5):646-656.
[2] LIN P,YIN H F,YAN C,et al.Association genetics identifies single nucleotide polymorphisms related to kernel oil content and quality in Camellia oleifera[J].Journal of agricultural food chemistry,2019,67(9):2547-2562.
[3] LI S J,HUANG H,MA X J,et al.Characterizations of MYB transcription factors in Camellia oleifera reveal the key regulators involved in oil biosynthesis[J].Horticulturae,2022,8(8):1-19.
[4] SU M H,SHIH M C,LIN K H.Chemical composition of seed oils in native Taiwanese Camellia species[J].Food chemistry,2014,156:369-373.
[5] YE S.Comparative lipidomic analysis on fresh kernels of two Camellia oleifera cultivars ‘Huaxin’and ‘Huashuo’at the mature stage[R].2023.
[6] LIN P,WANG K L,WANG Y P,et al.The genome of oil-Camellia and population genomics analysis provide insights into seed oil domestication[J].Genome biology,2022,23(1):1-21.
[7] SHEN T F,HUANG B,XU M,et al.The reference genome of Camellia chekiangoleosa provides insights into Camellia evolution and tea oil biosynthesis[J].Horticulture research,2022,9:1-11.
[8] GONG W F,XIAO S X,WANG L K,et al.Chromosome-level genome of Camellia lanceoleosa provides a valuable resource for understanding genome evolution and self-incompatibility[J].The plant journal,2022,110(3):881-898.
[9] ZHANG F,FENG L Y,LIN P F,et al.Chromosome-scale genome assembly of oil-tea tree Camellia crapnelliana[J].Scientific data,2024,11(1):1-8.
[10] ZHANG L,SHI Y,GONG W F,et al.The tetraploid Camellia oleifera genome provides insights into evolution,agronomic traits,and genetic architecture of oil Camellia plants[J].Cell reports,2024,43(11):1-24.
[11] ZHU H G,WANG F Q,XU Z P,et al.The complex hexaploid oil-Camellia genome traces back its phylogenomic history and multi-omics analysis of Camellia oil biosynthesis[J].Plant biotechnology journal,2024,22(10):2890-2906.
[12] HAO B Q,XIA Y Y,ZHANG Z Y,et al.Comparative analysis of the complete chloroplast genome sequences of four Camellia species[J].Brazilian journal of botany,2024,47(1):93-103.
[13] ZHANG W,ZHAO Y L,YANG G Y,et al.Determination of the evolutionary pressure on Camellia oleifera on Hainan Island using the complete chloroplast genome sequence[J].PeerJ,2019,7:1-25.
[14] CHEN J,GUO Y J,HU X W,et al.Comparison of the chloroplast genome sequences of 13 oil-tea Camellia samples and identification of an undetermined oil-tea camellia species from Hainan Province[J].Frontiers in plant science,2022,12:1-16.
[15] LU C,GAO L Z,ZHANG Q J.A high-quality genome assembly of the mitochondrial genome of the oil-tea tree Camellia gigantocarpa(Theaceae)[J].Diversity,2022,14(10):1-12.
[16] XIAO Z,GU Y Y,ZHOU J Q,et al.De novo assembly of the complete mitochondrial genomes of two Camellia-oil tree species reveals their multibranch conformation and evolutionary relationships[J].Scientific reports,2025,15(1):1-15.
[17] GU Y Y,YANG L Y,ZHOU J Q,et al.Mitochondrial genome study of Camellia oleifera revealed the tandem conserved gene cluster of nad5-nads in evolution[J].Frontiers in plant science,2024,15:1-15.
[18] LIANG H,QI H S,CHEN J L,et al.Assembly and analysis of the first complete mitochondrial genome sequencing of main Tea-oil Camellia cultivars Camellia drupifera(Theaceae):Revealed a multi-branch mitochondrial conformation for Camellia[J].BMC plant biology,2025,25(1):1-19.
[19] DU W,DING J,LI J B,et al.Co-regulatory effects of hormone and mRNA-miRNA module on flower bud formation of Camellia oleifera[J].Frontiers in plant science,2023,14:1-13.
[20] GUO H Y,ZHONG Q P,TIAN F,et al.Transcriptome analysis reveals putative induction of floral initiation by old leaves in tea-oil tree(Camellia oleifera ‘changlin53’)[J].International journal of molecular,2022,23(21):1-19.
[21] REN S S,JUAN L M,HE J C,et al.Expression analysis and interaction protein screening of CoZTL in Camellia oleifera Abel[J].Horticulturae,2023,9(7):1-14.
[22] LEI H J,SU S C,MA L Y,et al.Molecular cloning and functional characterization of CoFT1,a homolog of FLOWERING LOCUS T(FT)from Camellia oleifera[J].Gene,2017,626:215-226.
[23] YAN J D,HE J C,LI J A,et al.Analysis of Camellia oleifera transcriptome reveals key pathways and hub genes involved during different photoperiods[J].BMC plant biology,2022,22(1):1-13.
[24] HU J J,SONG H,CAO Z H,et al.Comparative analysis of transcriptome at different growth and development stages of Camellia oleifera[J].Russian journal of plant physiology,2024,71(3):1-11.
[25] ZENG H T,CHEN M J,ZHENG T,et al.Metabolomics analysis reveals the accumulation patterns of flavonoids and volatile compounds in Camellia oleifera petals with different color[J].Molecules,2023,28(21):1-16.
[26] ZENG H T,ZHENG T,TANG Q,et al.Integrative metabolome and transcriptome analyses reveal the coloration mechanism in Camellia oleifera petals with different color[J].BMC plant biology,2024,24(1):1-16.
[27] WANG Y,LI J A,GUO P R,et al.Ectopic expression of Camellia oleifera Abel.gibberellin 20-oxidase gene increased plant height and promoted secondary cell walls deposition in Arabidopsis[J].Planta,2023,258(3):1-18.
[28] ZHOU J Q,LU M Q,YU S S,et al.In-depth understanding of Camellia oleifera self-incompatibility by comparative transcriptome,proteome and metabolome[J].International journal of molecular sciences,2020,21(5):1-23.
[29] LI C,LONG Y,LU M Q,et al.Gene coexpression analysis reveals key pathways and hub genes related to late-acting self-incompatibility in Camellia oleifera[J].Frontiers in plant science,2023,13:1-17.
[30] HE Y F,SONG Q Q,CHEN S P,et al.Transcriptome analysis of self-and cross-pollinated pistils revealing candidate unigenes of self-incompatibility in Camellia oleifera[J].The journal of horticultural science biotechnology,2020,95(1):19-31.
[31] HE Y F,SONG Q Q,WU Y F,et al.TMT-based quantitative proteomic analysis reveals the crucial biological pathways involved in self-incompatibility responses in Camellia oleifera[J].International journal of molecular sciences,2020,21(6):1-18.
[32] 蒋思思,周俊琴,卢梦琪,等.油茶自、异交雌蕊 CAT 活性及相关基因克隆表达分析[J].植物科学学报,2022,40(6):810-819.
[33] LI C,LU M Q,ZHOU J Q,et al.Transcriptome analysis of the late-acting self-incompatibility associated with RNase T2 family in Camellia oleifera[J].Plants,2023,12(10):1-22.
[34] CHANG Y H,GONG W F,XU J M,et al.Integration of semi-in vivo assays and multi-omics data reveals the effect of galloylated catechins on self-pollen tube inhibition in Camellia oleifera[J].Horticulture research,2023,10(1):1-14.
[35] LU M Q,ZHOU J Q,JIANG S S,et al.The fasciclin-like arabinogalactan proteins of Camellia oil tree are involved in pollen tube growth[J].Plant science,2023,326:1-12.
[36] LU M Q,ZHOU J Q,LIU Y Y,et al.CoNPR1 and CoNPR3.1 are involved in SA-and MeSA-mediated growth of the pollen tube in Camellia oleifera[J].Physiologia plantarum,2021,172(4):2181-2190.
[37] KONG L S,ZHUO Y J,XU J R,et al.Identification of long non-coding RNAs and microRNAs involved in anther development in the tropical Camellia oleifera[J].BMC genomics,2022,23(1):1-18.
[38] 陈雨晴,杜兵帅,王胜楠,等.油菜胚珠败育的组织学特性及相关基因表达分析[J].北京林业大学学报,2023,45(9):9-20.
[39] ZHAO S Z,RONG J.Single-cell RNA-seq reveals a link of ovule abortion and sugar transport in Camellia oleifera[J].Frontiers in plant science,2024,15:1-16.
[40] LI H E,HU Y,GAO C,et al.Integrated SMRT technology with UMI RNA-Seq reveals the hub genes in stamen petalody in Camellia oleifera[J].Forests,2021,12(6):1-13.
[41] GAO X L,YANG Y,YE J W,et al.Abnormal calcium accumulation and ROS homeostasis-induced tapetal programmed cell death lead to pollen abortion of petaloid-type cytoplasmic male sterility in Camellia oleifera[J].Agronomy,2024,14(3):1-15.
[42] CHANG Y H,XU J M,GUO X M,et al.Tannase increases fruit set by interfering with self-incompatibility of Camellia oleifera[J].Industrial crops products,2024,210:1-11.
[43] LIU Y Y,ZHOU J Q,LU M Q,et al.The core jasmonic acid-signalling module CoCOI1/CoJAZ1/CoMYC2 are involved in Jas mediated growth of the pollen tube in Camellia oleifera[J].Current issues in molecular biology,2022,44(11):5405-5415.
[44] MA X L,CHEN S W,LI J W,et al.Transcriptome analysis unravels key pathways and hub genes related to immature fruit abscission in Camellia oleifera[J].Frontiers in plant science,2024,15:1-11.
[45] HU X,YANG M,GONG S F,et al.Ethylene-regulated immature fruit abscission is associated with higher expression of CoACO genes in Camellia oleifera[J].Royal society open science,2021,8(6):1-11.
[46] YANG M,HU X,OUYANG X,et al.Molecular cloning and characterization of three CoIDA genes in Camellia oleifera[J].Brazilian journal of botany,2021,44:391-400.
[47] SHENG Y,YAO X H,LIU L X,et al.Transcriptomic time-course sequencing:Insights into the cell wall macromolecule-mediated fruit dehiscence during ripening in Camellia oleifera[J].Plants,2023,12(18):1-15.
[48] SONG Q Q,CHEN S P,WU Y F,et al.Comparative transcriptome analyses of gene response to different light conditions of Camellia oleifera leaf using illumina and single-molecule real-time-based RNA-sequencing[J].Forests,2020,11(1):1-24.
[49] WU Y,MA L,ZHANG L S,et al.Photosynthetic carbon and nitrogen metabolism of Camellia oleifera Abel during acclimation to low light conditions[J].Journal of plant physiology,2022,278:1-11.
[50] HE Z L,LIU C X,WANG X N,et al.Leaf transcriptome and weight gene co-expression network analysis uncovers genes associated with photosynthetic efficiency in Camellia oleifera[J].Biochemical genetics,2021,59(2):398-421.
[51] YANG J H,CHEN B B,MANAN S,et al.Critical metabolic pathways and SAD/FADs,WRI1s,and DGATs cooperate for high-oleic acid oil production in developing oil tea(Camellia oleifera)seeds[J].Horticulture research,2022,9:1-23.
[52] 陈鸿鹏,谭晓风,谢耀坚,等.油茶CoSAD基因载体的构建、鉴定及功能分析[J].植物资源与环境学报,2015,24(2):11-18.
[53] WU B,RUAN C J,HAN P,et al.Comparative transcriptomic analysis of high-and low-oil Camellia oleifera reveals a coordinated mechanism for the regulation of upstream and downstream multigenes for high oleic acid accumulation[J].3 Biotech,2019,9(7):1-19.
[54] YE Z Q,MAO D,WANG Y J,et al.Comparative genome-wide identification of the fatty acid desaturase gene family in tea and oil tea[J].Plants,2024,13(11):1-15.
[55] 林萍,周长富,姚小华,等.普通油茶两个Δ-12脂肪酸脱氢酶基因序列特征及表达模式研究[J].林业科学研究,2016,29(5):743-751.
[56] YANG D Y,WANG R,LAI H G,et al.Comparative transcriptomic and lipidomic analysis of fatty acid accumulation in three Camellia oleifera varieties during seed maturing[J].Journal of agricultural food chemistry,2024,72(32):18257-18270.
[57] LIN P,WANG K L,ZHOU C F,et al.Seed transcriptomics analysis in Camellia oleifera uncovers genes associated with oil content and fatty acid composition[J].International journal of molecular sciences,2018,19(1):1-17.
[58] LI Z,WANG J Y,LONG H X,et al.Cloning and expression analysis of an aldehyde dehydrogenase gene from Camellia oleifera[J].Nanoscience and nanotechnology letters,2017,9(3):364-373.
[59] WU B,RUAN C J,ZHANG W C,et al.Comparative profiling of microRNA expression in the developing seeds of high-and low-oil tea oil camellia(Camellia oleifera)cultivars[EB/OL].(2019-07-17)[2024-08-25].https://doiorg/1021203/rs211530/v1.
[60] LIU X X,LUO X F,LUO K X,et al.Small RNA sequencing reveals dynamic microRNA expression of important nutrient metabolism during development of Camellia oleifera fruit[J].International journal of biological sciences,2019,15(2):416-429.
[61] FENG J L,YANG Z J,BAI W W,et al.Transcriptome comparative analysis of two Camellia species reveals lipid metabolism during mature seed natural drying[J].Trees,2017,31(6):1827-1848.
[62] GONG W F,SONG Q L,JI K,et al.Full-length transcriptome from Camellia oleifera seed provides insight into the transcript variants involved in oil biosynthesis[J].Journal of agricultural and food chemistry,2020,68(49):14670-14683.
[63] PENG S F,LU J,ZHANG Z,et al.Global transcriptome and correlation analysis reveal cultivar-specific molecular signatures associated with fruit development and fatty acid determination in Camellia oleifera Abel[J].International journal of genomics,2020,2020(1):1-16.
[64] YE Z C,WU Y G,UL HAQ MUHAMMAD Z,et al.Complementary transcriptome and proteome profiling in the mature seeds of Camellia oleifera from Hainan Island[J].PLoS One,2020,15(2):1-33.
[65] YE Z C,YU J,YAN W P,et al.Integrative iTRAQ-based proteomic and transcriptomic analysis reveals the accumulation patterns of key metabolites associated with oil quality during seed ripening of Camellia oleifera[J].Horticulture research,2021,8(1):1-26.
[66] CHEN M J,ZHANG Y,DU Z H,et al.Integrative metabolic and transcriptomic profiling in Camellia oleifera and Camellia meiocarpa uncover potential mechanisms that govern triacylglycerol degradation during seed desiccation[J].Plants,2023,12(14):1-22.
[67] ZHOU J,DU B S,CAO Y B,et al.Genome-wide identification of sucrose transporter genes in Camellia oleifera and characterization of CoSUT4[J].Journal of integrative agriculture,2025,24(9):3494-3510.
[68] YANG R,YAN Y D,ZENG Y L,et al.Correlation between squalene synthase promoter and WRKY transcription factor in Camellia oleifera[J].The journal of horticultural science biotechnology,2021,96(1):34-43.
[69] LI A R,DU Q H,ZENG Y L,et al.Light regulated CoWRKY15 acts on CoSQS promoter to promote squalene synthesis in Camellia oleifera seeds[J].International journal of molecular sciences,2024,25(20):1-20.
[70] DU Q,GE L,ZENG Y,et al.Identification and expression characterization of a WRKY transcription factor affecting squalene synthesis in Camellia oleifera[EB/OL].[2024-07-25].https://doiorg/1021203/rs3rs-4204 992/v1.
[71] SONG Q L,JI K,YU X R,et al.Dynamic metabolic and transcriptomic profiling reveal synthetic characters and regulators of flavonoid biosynthesis in Camellia oleifera seeds[J].Industrial crops products,2022,186:1-14.
[72] YANG L Y,GU Y Y,ZHOU J Q,et al.Whole-genome identification and analysis of multiple gene families reveal candidate genes for theasaponin biosynthesis in Camellia oleifera[J].International journal of molecular sciences,2022,23(12):1-20.
[73] LIU Y N,GENG Y Y,ZHANG S X,et al.Quantitative analysis and screening for key genes related to tea saponin in Camellia oleifera Abel.seeds[J].Food bioscience,2022,49:1-9.
[74] TAI Y L,WEI C L,YANG H,et al.Transcriptomic and phytochemical analysis of the biosynthesis of characteristic constituents in tea(Camellia sinensis)compared with oil tea(Camellia oleifera)[J].BMC plant biology,2015,15:1-13.
[75] 丁少净,钟秋平,袁婷婷,等.干旱胁迫对油茶花苞生长及产量的影响[J].南京林业大学学报(自然科学版),2017,41(5):197-202.
[76] 董斌,李荣喜,洪文泓,等.油茶干旱胁迫响应机制的研究进展[J].生物技术通报,2020,36(1):144-149.
[77] YE Z H,DU B S,ZHOU J,et al.Camellia oleifera CoSWEET10 is crucial for seed development and drought resistance by mediating sugar transport in transgenic Arabidopsis[J].Plants,2023,12(15):1-16.
[78] LIU L X,XU J,CHEN J J,et al.The LEA2 gene sub-family:Characterization,evolution,and potential functions in Camellia oleifera seed development and stress response[J].Scientia horticulturae,2023,322:1-12.
[79] DONG B,WU B,HONG W H,et al.Transcriptome analysis of the tea oil camellia(Camellia oleifera)reveals candidate drought stress genes[J].PLoS One,2017,12(7):1-25.
[80] YANG H,ZHOU H Y,YANG X N,et al.Transcriptomic analysis of Camellia oleifera in response to drought stress using high throughput RNA-seq[J].Russian journal of plant physiology,2017,64(5):728-737.
[81] ZHANG Z,XU Y M,LIU C X,et al.Cataloging the genetic response:Unveiling drought-responsive gene expression in oil tea camellia(Camellia oleifera Abel.)through transcriptomics[J].Life,2024,14(8):1-15.
[82] SHEN S S,YAN W P,XIE S A,et al.Comparison of morphological,physiological,and related gene expression responses to drought stress in five Camellia vietnamensis cultivars[J].Agronomy,2024,14(5):1-19.
[83] XING K F,ZHANG J,XIE H X,et al.Identification and analysis of MAPK cascade gene families of Camellia oleifera and their roles in response to cold stress[J].Molecular biology reports,2024,51(1):1-15.
[84] WU L L,LI J A,LI Z,et al.Transcriptomic analyses of Camellia oleifera ‘Huaxin’leaf reveal candidate genes related to long-term cold stress[J].International journal of molecular sciences,2020,21(3):1-21.
[85] WU L L,WANG Y J,GUO P R,et al.Metabonomic and transcriptomic analyses of Camellia oleifera flower buds treated with low-temperature stress during the flowering stage[J].Industrial crops products,2022,189:115874.
[86] WANG Y J,WU L L,SUN M H,et al.Transcriptomic and metabolomic insights on the molecular mechanisms of flower buds in responses to cold stress in two Camellia oleifera cultivars[J].Frontiers in plant science,2023,14:1126660.
[87] CHEN J M,YANG X Q,HUANG X M,et al.Leaf transcriptome analysis of a subtropical evergreen broadleaf plant,wild oil-tea camellia(Camellia oleifera),revealing candidate genes for cold acclimation[J].BMC genomics,2017,18(1):1-14.
[88] XIE H X,ZHANG J,CHENG J Y,et al.Field plus lab experiments help identify freezing tolerance and associated genes in subtropical evergreen broadleaf trees:A case study of Camellia oleifera[J].Frontiers in plant science,2023,14:1-19.
[89] XIE H X,XING K F,ZHANG J,et al.Genome survey and identification of key genes associated with freezing tolerance in genomic draft of hexaploid wild Camellia oleifera[J].The journal of horticultural science biotechnology,2024,99(3):326-335.
[90] XIE H X,XING K F,ZHOU J,et al.Single-nucleotide polymorphisms and copy number variations drive adaptive evolution to freezing stress in a subtropical evergreen broad-leaved tree:Hexaploid wild Camellia oleifera[J].Plant diversity,2025,47(2):214-228.
[91] ZHANG S P,GUO Y,LI S Z,et al.Functional analysis of CfSnf1 in the development and pathogenicity of anthracnose fungus Colletotrichum fructicola on tea-oil tree[J].BMC genetics,2019,20(1):1-9.
[92] ZHANG S P,GUO Y,CHEN S Q,et al.The histone acetyltransferase CfGcn5 regulates growth,development,and pathogenicity in the anthracnose fungus Colletotrichum fructicola on the tea-oil tree[J].Frontiers in microbiology,2021,12:1-13.
[93] ZHANG S P,LUO J,CHEN Y,et al.Vesicle trafficking mediated by small GTPase CfRab6 in association with CfRic1 and CfRgp1 governs growth,conidiation,and pathogenicity of Colletotrichum fructicola[J].International journal of biological macromolecules,2025,289:138988.
[94] LI J B,XIONG C W,RUAN D,et al.Identification of Camellia oleifera WRKY transcription factor genes and functional characterization of CoWRKY78[J].Frontiers in plant science,2023,14:1-13.
[95] ZHOU A T,TANG J R,DU Q J,et al.Comparative physiological and transcriptomic analyses provide induction resistance mechanisms of Bacillus tequilensis against Colletotrichum fructicola in Camellia oleifera[J].Plant physiology biochemistry,2024,214:108912.
[96] HE Y,MIAO X Y,XIA Y D,et al.The research of antagonistic endophytic bacterium Bacillus velezensis CSUFT-BV4 for growth promotion and induction of resistance to anthracnose in Camellia oleifera[J].Microorganisms,2024,12(4):1-23.
[97] ZHOU J Q,LIU Y Y,CHEN M,et al.Transcriptomic and metabolomic profiling of Camellia oleifera seedling roots treated with different nitrogen forms[J].Plant growth regulation,2023,99(2):215-227.
[98] CHEN J J,HAN X J,LIU L X,et al.Genome-wide detection of SPX family and profiling of CoSPX-MFS3 in regulating low-phosphate stress in tea-oil Camellia[J].International journal of molecular sciences,2023,24(14):1-17.
[99] CHEN J J,HAN X J,YE S C,et al.Integration of small RNA,degradome,and transcriptome sequencing data illustrates the mechanism of low phosphorus adaptation in Camellia oleifera[J].Frontiers in plant science,2022,13:1-16.
[100] SUN L L,ZHANG M S,LIU X M,et al.Aluminium is essential for root growth and development of tea plants(Camellia sinensis)[J].Journal of integrative plant biology,2020,62(7):984-997.
[101] 程俊森,王溢,李永泉,等.基于Label-free技术的高州油茶铝胁迫蛋白质组学研究[J].中南林业科技大学学报,2023,43(8):169-181.
[102] QU X J,ZHOU J Q,MASABNI J,et al.Phosphorus relieves aluminum toxicity in oil tea seedlings by regulating the metabolic profiling in the roots[J].Plant physiology biochemistry,2020,152:12-22.
[103] WANG Y,GUO P R,SHENG S,et al.Identification of CoDREB genes for drought and cold tolerance in Camellia oleifera[J].International journal of plant biology,2023,14(1):228-241.
[104] WANG B M,CHEN J J,CHEN L S,et al.Combined drought and heat stress in Camellia oleifera cultivars:Leaf characteristics,soluble sugar and protein contents,and Rubisco gene expression[J].Trees,2015,29(5):1483-1492.
[105] LI Q Y,ZHU W,SUN S M,et al.Unraveling the metabolic profile regulation of Camellia oilseeds under insect and heat stress:Insights into functional effects and mechanistic basis[J].Food chemistry:X,2024,23:101619.
基本信息:
DOI:
中图分类号:S794.4
引用信息:
[1]吴平凡,陈水莲,赵苗菲,等.油茶经济性状及相关生物学特性组学研究进展[J].安徽农业科学,2025,53(21):1-10+13.
基金信息:
中央财政林业科技推广示范项目([2023]GDTK-07); 广东省林业科技创新项目(2025JCKJCX005)