Page 135 - 《广西植物》2024年第7期
P. 135
7 期 林立等: 代谢组与转录组联合解析赤皮青冈叶片黄化变异机制 1 3 3 5
华中农业大学: 44-82.] 48(8): 1358 - 1366. [ 刘 新 亮ꎬ 李 先 民ꎬ 何 小 三ꎬ 等ꎬ
KIM EHꎬ LI XPꎬ RAZEGHIFARD Rꎬ et al.ꎬ 2009. The 2017. 植物叶色黄化突变分子机理的研究进展 [J]. 南方
multiple roles of light ̄harvesting chlorophyll a/ b ̄protein 农业学报ꎬ 48(8): 1358-1366.]
complexes define structure and optimize function of LIU YFꎬ PANG DDꎬ LI YYꎬ et al.ꎬ 2022. The screening and
Arabidopsis chloroplasts: A study using two chlorophyll b ̄ identification of key transcription factor genes for theacrine
less mutants [J]. BBA ̄Bioenergeticsꎬ 1787(8): 973-984. metabolism [J]. J Tea Sciꎬ 42(1): 41-50. [刘玉飞ꎬ 庞丹
KLOPFENSTEIN DVꎬ ZHANG LSꎬ PEDERSEN BSꎬ et al.ꎬ 丹ꎬ 李友勇ꎬ 等. 苦茶碱代谢关键转录因子基因的筛选
2018. GOATOOLS: a python library for gene ontology 鉴定 [J]. 茶叶科学ꎬ 42(1): 41-50.]
analyses [J]. Sci Repꎬ 8(1): 10872. LU XYꎬ CHEN Zꎬ TANG Fꎬ et al.ꎬ 2020. Combined
LI Bꎬ DEWEY CNꎬ 2011. RSEM: accurate transcript transcriptomic and metabolomic analysis reveals mechanism
quantification from RNA ̄Seq data with or without a of anthocyanin changes in Red Maple (Acer rubrum) leaves
reference genome [J]. BMC Bioinformꎬ 12(1): 323. [J]. Sci Silv Sinꎬ 56(1): 38-54. [陆小雨ꎬ 陈竹ꎬ 唐菲ꎬ
LI LJꎬ ZHANG ZWꎬ XUE Yꎬ et al.ꎬ 2022. Effects of low 等ꎬ 2020. 转录组与代谢组联合解析红花槭叶片中花青
temperature stress on chlorophyll metabolism of Zoysia 素苷变化机制 [J]. 林业科学ꎬ 56(1): 38-54.]
japonica [J]. J Beijing For Univꎬ 44(2): 91-99 [李丽菁ꎬ LU YRꎬ SUN Yꎬ FOO LYꎬ 2000. Novel pyranoanthocyanins
张智韦ꎬ 薛云ꎬ 等ꎬ 2022. 低温胁迫对日本结缕草叶绿素 from black currant seed [ J]. Tetrahedron Lettꎬ 41 (31):
代谢的影响 [J]. 北京林业大学学报ꎬ 44(2): 91-99.] 5975-5978.
LI SPꎬ ZHANG Yꎬ SHE JSꎬ et al.ꎬ 2023. The characteristics LUO Sꎬ LUO Tꎬ PENG Pꎬ et al.ꎬ 2015. Activity regulation and
and chloroplast ultrastructure of yellow leaf mutant CHL234 functions of Mg chelatase [J]. Plant Physiol Jꎬ 51(6): 806-
in eggplant [J]. Acta Hortic Sinꎬ 50(5): 1000-1008. [李 812. [罗莎ꎬ 罗韬ꎬ 彭鹏ꎬ 等ꎬ 2015. 镁离子螯合酶活性调
淑培ꎬ 张映ꎬ 舒金帅ꎬ 等ꎬ 2023. 茄子叶色黄化突变体 控及其功能 [J]. 植物生理学报ꎬ 51(6): 806-812.]
CHL234 的特性及其叶绿体超微结构 [J]. 园艺学报ꎬ LUO Tꎬ ZHOU ZFꎬ DENG YCꎬ et al.ꎬ 2022. Transcriptome
50(5): 1000-1008.] and metabolome analyses reveal new insights into
LI WXꎬ HE ZCꎬ YANG SBꎬ et al.ꎬ 2019. Construction and chlorophyllꎬphotosynthesisꎬmetal ion and phenylpropanoids
analysis of a library of miRNA in gold ̄coloured mutant related pathways during sugarcane ratoon chlorosis [ J].
leaves of Ginkgo biloba L. [ J]. Folia Horticꎬ 31(1): BMC Plant Biolꎬ 22(1): 1-15.
81-92. LYU YZꎬ DONG XYꎬ HUANG LBꎬ et al.ꎬ 2017. De novo
LI WZꎬ GODZIK Aꎬ 2006. Cd ̄hit: a fast program for clustering assembly of Koelreuteria transcriptome and analysis of major
and comparing large sets of protein or nucleotide sequences gene related to leaf etiolation [J]. S Afr J Botꎬ 113(1):
[J]. Bioinformaticsꎬ 22(13): 1658-1659. 355-361.
LI YHꎬ WANG BHꎬ DAI ZYꎬ et al.ꎬ 2012. Morphological MAEKAWA Sꎬ TAKABAYASHI Aꎬ REYES THꎬ et al.ꎬ
structure and genetic mapping of new leaf ̄color mutant gene 2015. Pale ̄green phenotype of atl31 atl6 double mutant
in rice (Oryza sativa) [J]. Rice Sciꎬ 19(2): 79-85. leaves is caused by disruption of 5 ̄aminolevulinic acid
LIN XYꎬ SHAO SXꎬ WANG PJꎬ et al.ꎬ 2022. The albino biosynthesis in Arabidopsis thaliana [ J ]. PLoS ONEꎬ
mechanism of a new theanine ̄rich tea cultivar ‘Fuhuang 2’ 10(2): e0117662.
[J]. Chin J Biotechnolꎬ 38(10): 3956-3972. [林馨颖ꎬ MANJAYA JGꎬ NANDANWAR RSꎬ 2007. Genetic
邵淑贤ꎬ 王鹏杰ꎬ 等ꎬ 2022. 高茶氨酸茶树新品系‘福黄 improvement of soybean variety JS 80- 21 through induced
2 号’ 黄 化 变 异 机 理 [ J]. 生 物 工 程 学 报ꎬ 38(10): mutations [J]. Plant Mutat Repꎬ 1(3): 36-40.
3956-3972.] MARUM Lꎬ MIGUEL Aꎬ RICARDO CPꎬ et al.ꎬ 2012.
LIU JWꎬ 2016. Omics ̄based study on the metabolism of C/ N Reference gene selection for quantitative real ̄time PCR
and biosynthesis of main quality related components in tea normalization in Quercus suber [ J ]. PLoS ONEꎬ
plants affected by nitrogen [D]. Beijing: Chinese Academy 7(4): e35113.
of Agricultural Sciences: 1-6. [刘健伟ꎬ 2016. 基于组学 MICHAEL ILꎬ HUBER Wꎬ ANDERS Sꎬ 2014. Moderated
技术研究氮素对于茶树碳氮代谢及主要品质成分生物 estimation of fold change and dispersion for RNA ̄seq data
合成的影响 [D]. 北京: 中国农业科学院: 1-6.] with DESeq2 [J]. Genome Biolꎬ 15(12): 550.
LIU LLꎬ LI YYꎬ SHE GBꎬ et al.ꎬ 2018. Metabolite profiling MOCHIZUKI Nꎬ BRUSSLAN JAꎬ LARKIN Rꎬ et al.ꎬ 2001.
and transcriptomic analyses reveal an essential role of Arabidopsis genomes uncoupled 5 (GUN5) mutant reveals
UVR8 ̄mediated signal transduction pathway in regulating the involvement of Mg ̄chelatase H subunit in plastid ̄to ̄
flavonoid biosynthesis in tea plants (Camellia sinensis) in nucleus signal transduction [ J]. Proc Natl Acad Sciꎬ
response to shading [J]. BMC Plant Biolꎬ 18(1): 233. 98(4): 2053-2058.
LIU XLꎬ LI XMꎬ HE XSꎬ et al.ꎬ 2017. A review: molecular OUYANG ZYꎬ OUYANG SLꎬ WU JYꎬ et al.ꎬ 2021. Research
mechanism of plant yellow leaf mutation [J]. J S Agricꎬ progress of precious commercial tree species Cyclobalanopsis
