3个竹种Rubisco活化酶基因鉴定及其功能

doi:10.11707/j.1001-7488.LYKX20240721

摘要/Abstract

摘要：

目的: Rubisco活化酶（Rca）作为Rubisco的催化伴侣，具有促进CO₂固定的作用。对毛竹、芸香竹和莪莉竹的Rca基因进行全基因组鉴定与系统分析，并聚焦毛竹的PeRca1-β和PeRca2-α基因功能，为解析Rcas在竹子光合作用中的分子机制提供参考。方法: 以水稻中已知的Rca氨基酸序列为诱饵，在毛竹、芸香竹和莪莉竹基因组数据库中进行BLASTP比对，获得不同竹种Rca基因家族成员，并利用生物信息学方法进行系统分析；采用实时荧光定量PCR（RT-qPCR）技术对毛竹Rca基因在不同组织以及不同光照环境下叶片中的表达模式进行分析；利用激光共聚焦显微镜观察毛竹Rca的亚细胞定位；基于转录组数据构建毛竹Rca基因的共表达网络；通过双荧光素酶报告（DLR）试验验证转录因子与毛竹Rca基因的调控关系；利用原位基因编辑技术对毛竹Rca基因进行功能研究。结果: 在毛竹、芸香竹和莪莉竹中分别鉴定到3个、3个和2个Rca基因家族成员，其中PeRca3-α和OlaRca2-α具有更长的内含子，且在进化树中PeRca3-α和OlaRca2-α聚类到独立分支，可能分化出新的功能。烟草表皮细胞的亚细胞定位试验证实PeRcas定位于叶绿体。RT-qPCR结果表明，PeRcas在毛竹不同组织中表达水平存在一定差异，且对光照时间和强度的响应能力不同，其中PeRca1-β和PeRca2-α在叶片中表达量较高，且受光照诱导表达，而弱光和黑暗抑制其表达。共表达网络分析发现，PeRca1-β和PeRca2-α均与PeGLK1-1具有较高相关性，DLR证实PeGLK1-1能够与其启动子结合并激活其表达。原位基因编辑后，毛竹叶片中PeRca1-β和PeRca2-α的表达量显著降低，且光合电子传递速率和实际光合量子产量均显著降低。结论: 毛竹和芸香竹中均有3个Rcas成员，莪莉竹中有2个Rcas成员，在进化上呈现高度保守性。PeRcas的表达水平在毛竹绿色组织中较高，且受光照的诱导以及弱光和黑暗的抑制，其中PeRca1-β和PeRca2-α的表达受PeGLK1-1调控。原位基因编辑能够降低毛竹叶片中PeRca1-β和PeRca2-α的表达量，导致光合作用效率和光能利用率下降。研究结果可为揭示竹子Rcas的功能提供依据，对全面解析竹子高效光合固碳的分子机制具有重要参考价值。

关键词: 毛竹, Rubisco活化酶基因, 亚细胞定位, 表达模式, 原位基因编辑

Abstract:

Objective: Bamboo is an important forest plant resource with highly efficient photosynthetic carbon fixation ability. In photosynthesis, CO₂ fixation is catalyzed by ribulose-1,5-bisphosphate carboxylase/oxygen (Rubisco), while Rubisco activase (Rca) acts as a catalytic chaperone of Rubisco and facilitates CO₂ fixation. To clarify the function of Rcas in bamboo photosynthesis, the Rca genes in Phyllostachys edulis (moso bamboo), Bambusa amplexicaulis, and Olyra latifolia were identified and analyzed systematically across the whole genomes. Furthermore, the function of PeRca1-β and PeRca2-α in moso bamboo was focused on, in order to provide reference for elucidating the molecular mechanism of Rcas in bamboo photosynthesis. Method: The known Rca amino acid sequences in rice (Oryza sativa) were used as bait, BLASTP was performed in the genome databases of P. edulis, B. amplexicaulis, and O. latifolia to obtain homologous sequences of Rca in three different bamboo species, and then systematic analyses were conducted using bioinformatics method. The expression patterns of Rca genes in different tissues and leaves under different light conditions were analyzed by RT-qPCR. The subcellular localization of Rcas from moso bamboo was observed by laser confocal microscopy. The co-expression network of PeRcas was constructed based on transcriptome data. The regulatory relationship between transcription factor and PeRcas was verified by dual luciferase reporter (DLR) assay. The function of PeRcas was investigated by in-planta gene editing in moso bamboo leaves. Result: In this study, three, three, and two members of Rcas gene family were identified in moso bamboo, B. amplexicaulis and O. latifolia, respectively. Among them, PeRca3-α in moso bamboo and OlaRca2-α in O. latifolia had longer introns, and they were clustered into an independent branch in the phylogenetic tree, which might have evolved new functions. The subcellular localization experiment in tobacco epidermal cells confirmed that PeRcas were located in chloroplasts. RT-qPCR results showed that the expression levels of PeRcas in different tissues of moso bamboo were significantly different and their response to lighting time and intensity were also diverse. Among them, PeRca1-β and PeRca2-α had higher expression levels in leaves and were induced by light, while weak light and darkness inhibited their expression. Co-expression network analysis revealed that both PeRca1-β and PeRca2-α had higher correlation with PeGLK1-1, and DLR assay confirmed that PeGLK1-1 could directly bind to the promoters and activated their expression. After in-planta gene editing, the expression levels of PeRca1-β and PeRca2-α in bamboo leaves were significantly decreased, and both the photosynthetic electron transfer rate and actual photosynthetic quantum yield were significantly reduced. Conclusion: There are three Rca members in both moso bamboo and B. amplexicaulis, and two Rca members in O. latifolia, exhibiting high conservation in evolution. The expression levels of PeRcas are significantly higher in green tissues of moso bamboo, and are induced by light and inhibited by weak light and darkness. The expression of PeRca1-β and PeRca2-α is regulated by PeGLK1-1. In-planta gene editing can reduce the expression levels of PeRca1-β and PeRca2-α in moso bamboo leaves, leading to a decrease in photosynthetic efficiency and light energy utilization. These results provide evidence for revealing the function of Rcas in bamboo and have important reference value for fully elucidating the molecular mechanism of efficient photosynthetic carbon fixation in bamboo.

Key words: Phyllostachys edulis, Rubisco activase, subcellular localization, expression pattern, in-planta gene editing

中图分类号:

S718.46

李慧,王清楠,朱成磊,孙化雨,狄小琳,高志民. 3个竹种Rubisco活化酶基因鉴定及其功能[J]. 林业科学, 2025, 61(11): 35-44.

Hui Li,Qingnan Wang,Chenglei Zhu,Huayu Sun,Xiaolin Di,Zhimin Gao. Identification and Function of Rubisco Activase Gene Family in Three Bamboo Species[J]. Scientia Silvae Sinicae, 2025, 61(11): 35-44.

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基因 Gene	正向引物 Forward primer （5′–3′）	反向引物 Reverse primer （5′–3′）
PeRca1-β	GGTGACTTCGGCCGTGAA	GGTGACTTCGGCCGTGAA
PeRca2-α	TACGACGATGAGGTGCGC	TACGACGATGAGGTGCGC
PeRca3-α	TACGACGATGAGGTGCGC	GAGCCGCTTCCCGATGTT
PeGAPDH	CAAGGCTGTTGGCAAGGTTC	CATATGAGGCAGACTTCTCGATTC

基因 Gene	基因登录号 Accession ID	蛋白长度 Protein length/aa	理论等电点 Isoelectric point	亲水性总平均值 Grand average of hydropathicity (GRAVY)	转运肽长度 Transit peptide length/aa
PeRca1-β	PH02Gene18719.t1	427	6.93	–0.376	48
PeRca2-α	PH02Gene23790.t1	463	6.20	–0.411	48
PeRca3-α	PH02Gene23791.t1	489	6.15	–0.377	48
BamRca1-β	Bam009417.1	430	6.08	–0.380	48
BamRca2-α	Bam022659.1	465	5.68	–0.439	47
BamRca3-β	Bam031930.1	430	6.08	–0.368	48
OlaRca1-β	Ola008925.1	428	6.49	–0.423	48
OlaRca2-α	Ola008927.1	465	6.20	–0.372	47

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