拟松材线虫G蛋白α亚基Bmu-gpa-1表达特性及功能

doi:10.11707/j.1001-7488.20220410

摘要/Abstract

摘要：

目的: 研究与交配行为相关的拟松材线虫G蛋白α亚基Bmu-gpa-1基因的表达特性及生物学功能，为拟松材线虫的种内交配繁殖分子机制研究提供依据。方法: 根据拟松材线虫基因组数据设计引物克隆Bmu-gpa-1基因。对Bmu-gpa-1进行序列分析、系统发育分析和蛋白结构预测等生物信息学分析。利用实时荧光定量PCR技术和原位杂交技术探究Bmu-gpa-1基因在拟松材线虫各个龄期的表达水平和表达部位，明确其时空动态表达特性。利用RNA干扰技术探究该基因在拟松材线虫交配繁殖行为中的作用，并通过实时荧光定量PCR技术检测RNA干扰的效率。结果: Bmu-gpa-1基因全长为1 780 bp，CDS全长为1 065 bp，编码354个氨基酸。进化分析表示该基因与秀丽隐杆线虫gpa-1基因隶属于同一G蛋白α亚基家族。荧光定量PCR结果及转录组结果均表明Bmu-gpa-1基因在拟松材线虫各个发育阶段均有表达，2龄期和3龄期表达水平较高，胚胎期次之，4龄期和成虫期表达水平较低且基因表达水平具有雌、雄虫差异性，即雄虫的基因表达水平显著高于雌虫。原位杂交结果表明，Bmu-gpa-1基因在拟松材线虫体内广泛表达，胚胎发育初期呈散点状表达，胚胎发育后期过渡到全胚胎表达，2龄期全身表达，3龄期和4龄期进一步集中在肠道和性腺处表达，成虫期则出现雌、雄虫差异性表达，即在雌虫的阴户、雄虫的交合刺和尾部表达。交配试验结果显示，沉默Bmu-gpa-1基因后，拟松材线虫雄虫与正常雌虫的交配次数显著增加，交配时长显著缩短，繁殖能力显著下降，而雌虫被干扰后在交配繁殖行为上则无明显异常，推测该基因可以负向调控拟松材线虫雄虫的交配行为，但对雌虫影响较弱。结论: 拟松材线虫Bmu-gpa-1基因是G蛋白α亚基家族中的一员，基因表达水平及表达部位皆具有雌、雄虫差异性。沉默该基因可以改变雄虫的交配行为，雄虫表现出交配次数增加、交配时长减短和交配后雌虫产卵数减少等交配质量下降特征，但对雌虫影响较弱，这说明Bmu-gpa-1基因对拟松材线虫雄虫的交配繁殖行为具有明显的调控功能。

关键词: 拟松材线虫, Bmu-gpa-1, 交配行为, 繁殖能力, 雌、雄虫差异性

Abstract:

Objective: As a member of the pine wood nematode disease system, Bursaphelenchus mucronatus has caused serious ecological and economic losses in China due to its efficient and frequent mating behavior. We therefore investigated Bmu-gpa-1 gene of G protein that is related to mating behaviour, and its expression characteristics and its role in mating behavior in B. mucronatus, which would provide a basis for the study of the molecular mechanisms for mating and reproduction in B. mucronatus. Method: Bmu-gpa-1 gene was cloned by PCR based on the genomic data of B.mucronatus. The sequence alignment, phylogenetic analysis and protein structure prediction were conducted to clarify its evolutional relationship with other species. The RT-qPCR and in situ hybridization were used to analyze the gene expression level and expression location in different development stages to reveal its temporal and spatial dynamic expression characteristics. The gene Bmu-gpa-1 was silenced by RNAi to investigate the effects on mating behavior and reproductive capability. In the meanwhile, RT-qPCR was used to check the efficiency of RNAi. Result: The full-length of Bmu-gpa-1 gene is 1 780 bp, including 1 056 bp CDS, encoding 354 amino acids. Phylogenetic analysis indicated that the gene belonged to the same G protein alpha subunit family as gpa-1 in Caenorhabditis elegans. The results of RT-qPCR and transcriptomes showed that Bmu-gpa-1 was expressed in all developmental stages of B. mucronatus, with the expression level highest in the second and third juvenile stages, followed by embryonic stage, and the expression level in the fourth juvenile stage and the adult stage was the lowest. Meanwhile, we found the gene expression level has sexual dimorphism, showing a higher expression level in the males than that in the females. The result of mRNA in situ hybridization showed that Bmu-gpa-1 was expressed broadly in the nematodes. In the embryonic stage, expression location changed dramatically from sporadic dots to whole embryos. In the second juvenile stages, it was expressed in the whole bodies. In the third and fourth juvenile stages, it was mostly located in the intestinal tracts and gonads. In the adult stage, the expression location had sexual dimorphism, it was seen in the vulvas of females, whereas it was only observed in the spicules and tails in males. In the mating test, the males after silencing Bmu-gpa-1 had more frequent and faster mating behavior events than those of controls, but had fewer offspring. However, there were no significant changes in the mating and reproductive behavior of the RNAi-treated females. It is speculated that Bmu-gpa-1 gene can negatively regulate the mating behavior for males, but not for females. Conclusion: Bmu-gpa-1 is a member of the G protein alpha subunit family. It has sexual dimorphism in the expression level and location. Our result indicate the males treated by RNAi have stronger capacity in signal transduction and massive invalid frequent mating behaviors, but not happened in females. It is suggested that Bmu-gpa-1 plays a negative role in the signal transduction of male nematodes and regulates their mating behaviors and fecundity in B. mucronatus.

Key words: Bursaphelenchus mucronatus, Bmu-gpa-1, mating behavior, fecundity, sexual dimorphism

中图分类号:

S763

马芮,刘文义,余红仕,周立峰,胡加付. 拟松材线虫G蛋白α亚基Bmu-gpa-1表达特性及功能[J]. 林业科学, 2022, 58(4): 95-103.

Rui Ma,Wenyi Liu,Hongshi Yu,Lifeng Zhou,Jiafu Hu. Expression Characteristics and Functions of G Protein Alpha Subunit Bmu-gpa-1 in Bursaphelenchus mucronatus[J]. Scientia Silvae Sinicae, 2022, 58(4): 95-103.

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处理 Treatment	交配率 Mating rate(%)	交配次数 Number of mating	交配时长 Mating time/min	有效交配率 Effective mating rate(%)	产卵量 Number of offspring
CK♀+CK♂	68.75±1.47 b	1.05±0.04 b	22.14±0.78 a	83.45±0.03 a	14.28±0.66 a
RNAi♀+CK♂	66.67±0.85 b	1.19±0.06 b	22.11±0.67 a	76.62±0.02 a	12.63±0.98 a
CK♀+RNAi♂	82.29±0.85 a	1.47±0.04 a	15.19±0.47 b	59.54±0.02 b	8.07±0.69 b

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