靶向小菜蛾PxGNBP3的RNAi增效绿僵菌构建及其免疫调控机制

doi:10.3864/j.issn.0578-1752.2026.03.007

摘要/Abstract

摘要：

【目的】革兰氏阴性菌识别蛋白（Gram-negative binding protein，GNBP），又称β-1,3-葡聚糖识别蛋白，是昆虫中一类重要的模式识别受体（pattern recognition receptor，PRR），在先天免疫过程中发挥关键作用。本研究旨在系统鉴定小菜蛾（Plutella xylostella）GNBP基因家族成员，分析其结构特征与表达模式，筛选并验证关键靶基因，以期揭示小菜蛾应对病原侵染的先天免疫机制与进化适应，为开发新型生物防治策略提供理论依据与潜在靶点。【方法】基于小菜蛾全基因组数据，对GNBP基因家族成员进行鉴定；综合利用生物信息学方法分析其结构特征与进化关系，并采用AlphaFold3预测其三维结构。此外，结合公共转录组数据与实时荧光定量PCR（RT-qPCR）技术，检测该家族成员在不同组织以及白僵菌（Beauveria bassiana）和金龟子绿僵菌（Metarhizium anisopliae）侵染后的表达模式。构建携带pSilent-PxGNBP3的重组绿僵菌，并通过RT-qPCR检测侵染后PxGNBP3及下游抗菌肽基因的表达水平，同时利用生物测定评估不同菌株对小菜蛾的致病力。【结果】共鉴定出10个小菜蛾PxGNBP，其中PxβGRP4位于22号染色体，属于葡聚糖酶亚家族；其余9个成员位于29号染色体，属于PRR亚家族。系统进化及染色体定位分析表明该家族存在串联重复现象。保守基序分析显示，PxGNBP的N端结构域保守性低于C端；除PxβGRP4外，其余成员的葡聚糖酶关键催化位点均发生突变。三维结构预测结果表明，除PxβGRP4和PxβGRP3外，其余成员均具有典型GNBP蛋白结构；PxβGRP3的C端存在一个与Carbohydrate-binding module 39（CBM39）相似但不同的结构片段。表达谱分析发现，大多数成员在两种真菌侵染后均呈现先上升后下降的时序表达模式。RNA干扰（RNAi）试验表明，重组绿僵菌能够有效抑制PxGNBP3的表达，从而导致抗菌肽表达水平显著下降及宿主存活率降低；且重组菌株的毒力显著高于野生型，并随浓度升高而增强。【结论】鉴定出小菜蛾10个GNBP家族成员，PxβGRP3和PxGNBP3-2在结构上具有特殊性；该家族在真菌侵染中呈现时序性调控表达模式；利用构建重组绿僵菌方式成功实现了对PxGNBP3的体内RNAi功能验证。研究结果可为阐明小菜蛾先天免疫机制及开发新型生物防治靶标提供重要依据。

关键词: 革兰氏阴性菌识别蛋白, 小菜蛾, 金龟子绿僵菌, RNA干扰, 生物防治

Abstract:

【Objective】Gram-negative binding proteins (GNBPs), also known as β-1,3-glucan recognition proteins, represent a class of crucial pattern recognition receptors (PRRs) in insects and play pivotal roles in the innate immune response. This study aimed to systematically identify members of the PxGNBP gene family in the diamondback moth (Plutella xylostella), analyze their structural characteristics and expression patterns, as well as screen and validate key target genes. The findings are expected to reveal the innate immune mechanisms and evolutionary adaptations of P. xylostella in response to pathogenic infection, thereby providing theoretical foundations and potential targets for the development of novel biological control. 【Method】Based on the whole-genome data of P. xylostella, members of the PxGNBP gene family were identified. Bioinformatic approaches were comprehensively employed to analyze their structural characteristics and evolutionary relationships, and AlphaFold3 was used to predict their three-dimensional structures. In addition, combined with public transcriptome data and quantitative real-time polymerase chain reaction (RT-qPCR) technology, the expression patterns of these family members in different tissues and post-infection with Beauveria bassiana and Metarhizium anisopliae were detected. Recombinant M. anisopliae strains carrying pSilent-PxGNBP3 were constructed. The expression levels of PxGNBP3 and downstream antimicrobial peptide genes post-infection were determined via RT-qPCR, and the pathogenicity of different strains against P. xylostella was evaluated using bioassays. 【Result】A total of 10 PxGNBP members were identified in P. xylostella. Among them, PxβGRP4 is located on chromosome 22 and belongs to the glucanase subfamily, while the remaining 9 members are located on chromosome 29 and belong to the PRR subfamily. Phylogenetic and chromosome location analyses suggested the occurrence of tandem duplication events within this gene family. Conserved motif analysis indicated that the N-terminal domain of PxGNBP exhibited lower conservation compared to the C-terminal domain. Except for PxβGRP4, the key catalytic sites of glucanase in other members were mutated. Three-dimensional structure predictions revealed that all members, except PxβGRP4 and PxβGRP3, possessed the typical GNBP protein structure; the C-terminus of PxβGRP3 contained a structural fragment that was similar but not identical to Carbohydrate-binding module 39 (CBM39). Expression profile analysis demonstrated that most members exhibited a time-series expression pattern of first increasing and then decreasing after infection with the two fungi. RNA interference (RNAi) assays showed that the recombinant M. anisopliae strains could effectively suppress the expression of PxGNBP3, leading to a significant reduction in antimicrobial peptide expression levels and a decrease in host survival rate. Moreover, the virulence of recombinant strains was significantly higher than that of the wild-type strain and enhanced with increasing concentration. 【Conclusion】Ten members of the GNBP gene family were identified in P. xylostella, with PxβGRP3 and PxGNBP3-2 showing structural specificity. This gene family exhibited a time-series regulatory expression pattern in response to fungal infection. In vivo functional validation of PxGNBP3 via RNAi was successfully achieved using the constructed recombinant M. anisopliae strains. The results provide important insights for elucidating the innate immune mechanisms of P. xylostella and developing novel targets for biological control.

Key words: Gram-negative binding protein (GNBP), Plutella xylostella, Metarhizium anisopliae, RNAi, biological control

鄢文英, 张元珍, 吴洪鑫, 庞锐, 陈泽鹏, 金丰良, 许小霞. 靶向小菜蛾PxGNBP3的RNAi增效绿僵菌构建及其免疫调控机制[J]. 中国农业科学, 2026, 59(3): 556-574.

YAN WenYing, ZHANG YuanZhen, WU HongXin, PANG Rui, CHEN ZePeng, JIN FengLiang, XU XiaoXia. Construction of an RNAi-Enhanced Metarhizium anisopliae Targeting PxGNBP3 and Its Immunoregulatory Mechanism in Plutella xylostella[J]. Scientia Agricultura Sinica, 2026, 59(3): 556-574.

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基因Gene	引物及序列Primer and sequence (5′-3′)	基因Gene	引物及序列Primer and sequence (5′-3′)
PxβGRP4	PxβGRP4_F: CGTTATGGCAGCAAGATG	PxGNBP3	PxGNBP3-Xho I F1: GCG CTCGAGCGGAACACAAGATTGCTTTG
PxβGRP4	PxβGRP4_R: TTACGACCGTTCCAGAAG		PxGNBP3-Hind III R1: GCC AAGCTTTCAAGTTGCCTCTGGCTGT
PxβGRP3	PxβGRP3_F: GTATACGGCAACGGTCGCTA		PxGNBP3-Kpn I F2: GCC GGTACCCGGAACACAAGATTGCTTTG
PxβGRP3	PxβGRP3_R: AATCGTTCGATCCGCCTACC		PxGNBP3-Sph I R2: GCC GCATGCTCAAGTTGCCTCTGGCTGT
PxGNBP3-1	PxGNBP3-1_R: CAGCAGCCAATAGCGGTTTC	GFP	GFP-Xho I F1: CCG CTCGAGATGGTGAGCAAGGGCGAG
PxGNBP3-1	PxGNBP3-1_F: TGGCTACAAACCAGGGCATT		GFP-Hind III R1: AGC AAGCTTTACTTGTACAGCTCGTCCATGCC
PxGNBP3-2	PxGNBP3-2_R: AACTCCTTGTTCCACTCTTC		GFP-Kpn I F2: CGG GGTACCATGGTGAGCAAGGGCGAG
PxGNBP3-2	PxGNBP3-2_F: GACGGTAACTACGCATCC		GFP-Sph I R2: ACAT GCATGCTACTTGTACAGCTCGTCCATGCC
PxGNBP3-3	PxGNBP3-3_R: ATCATTGGACCCACCGACAC	Moricin	Mor-qF: GTCAACGTCAACGCCCTCAAG
PxGNBP3-3	PxGNBP3-3_F: GACCTCAGGGACACAACTGG	Moricin	Mor-qR: GTCCACCCCTGGCACTGTCTA
PxGNBP3	PxGNBP3_R: ATACTATGAGGTCTGGTGTC	Lysozyme1	Lys1-qF: CGCATTGTCTGAAGGGAAGGT
PxGNBP3	PxGNBP3_F: CAAGATTACGGCAATAAGGT	Lysozyme1	Lys1-qR: TTGATCTGGAACAGCCCGTAG
PxGNBP3-5	PxGNBP3-5_R: TGTTCTCGGTGTCATTCG	Lysozyme2	Lys2-qF: CCCTGAAAGTAGTTGCTGGAT
PxGNBP3-5	PxGNBP3-5_F: CGCAGATTGAGGCACTAT	Lysozyme2	Lys2-qR: GCCTCTACACGGCTTCGTTAT
PxGNBP3-6	PxGNBP3-6_R: CCGTTGGTTGTTGTTCCT	Cecropin1	Cep1-qF: TATACATTATTTAACCCGTAAAT
PxGNBP3-6	PxGNBP3-6_F: CTGGTCATCTCCGTATGTG	Cecropin1	Cep1-qR: GTCGCTGTCATCGGACAAGCCAC
PxGNBP2	PxGNBP2_R: GCATGTGTTGGTTAAGTCC	Cecropin2	Cep2-qF: CATCACGGATGTGCTGTCCCACT
PxGNBP2	PxGNBP2_F: TCCTGAAGAGCCTGATTATC	Cecropin2	Cep2-qR: GGAATAAAAGATTCCAATTTCAA
PxβGRP1	PxβGRP1_R: CGACGAATCCTTCAACAGT	Cecropin3	Cep3-qF: TACTTCTTCTTCACGGTTGTCG
PxβGRP1	PxβGRP1_F: TCCAGAGACATCACCAGAC	Cecropin3	Cep3-qR: CCCAATATGCTGGATGCTTGTC
RPS13	RPS13-F: TCAGGCTTATTCTCGTCG	Gloverin	Glo-qF: TGTGCCGTGGCTCAAGTTTC
RPS13	RPS13-R: GCTGTGCTGGATTCGTAC	Gloverin	Glo-qR: CCTGACGGTAGCCCGCCTTA