Department of Horticulture and Crop Science, The Ohio State University, Columbus, OH, 43210, USA.
Center for Applied Plant Sciences, The Ohio State University, Columbus, OH, 43210, USA.
BMC Plant Biol. 2024 Jun 27;24(1):609. doi: 10.1186/s12870-024-05260-9.
Grapevine (Vitis) is one of the world's most valuable fruit crops, but insect herbivory can decrease yields. Understanding insect herbivory resistance is critical to mitigating these losses. Vitis labrusca, a wild North American grapevine species, has been leveraged in breeding programs to generate hybrid grapevines with enhanced abiotic and biotic stress resistance, rendering it a valuable genetic resource for sustainable viticulture. This study assessed the resistance of V. labrusca acc. 'GREM4' and Vitis vinifera cv. 'PN40024' grapevines to Popillia japonica (Japanese beetle) herbivory and identified morphological and genetic adaptations underlying this putative resistance.
'GREM4' displayed greater resistance to beetle herbivory compared to 'PN40024' in both choice and no-choice herbivory assays spanning periods of 30 min to 19 h. 'GREM4' had significantly higher average leaf trichome densities than 'PN40024' and beetles preferred to feed on the side of leaves with fewer trichomes. When leaves from each species that specifically did not differ in trichome densities were fed on by beetles, significantly less leaf area was damaged in 'GREM4' (3.29mm) compared to 'PN40024' (9.80mm), suggesting additional factors beyond trichomes contributed to insect herbivory resistance in 'GREM4'. Comparative transcriptomic analyses revealed 'GREM4' exhibited greater constitutive (0 h) expression of defense response and secondary metabolite biosynthesis genes compared to 'PN40024', indicative of heightened constitutive defenses. Upon herbivory, 'GREM4' displayed a greater number of differentially expressed genes (690) compared to 'PN40024' (502), suggesting a broader response. Genes up-regulated in 'GREM4' were enriched in terpene biosynthesis, flavonoid biosynthesis, phytohormone signaling, and disease defense-related functions, likely contributing to heighted insect herbivory defense, while genes differentially expressed in 'PN40024' under herbivory were enriched in xyloglucan, cell wall formation, and calcium ion binding. The majority of genes implicated in insect herbivory defense were orthologs with specific expression patterns in 'GREM4' and 'PN40024', but some paralogous and genome-specific genes also likely contributed to conferring resistance.
Our findings suggest that 'GREM4' insect herbivory resistance was attributed to a combination of factors, including trichomes and unique constitutive and inducible expression of genes implicated in terpene, flavonoid, and phenylpropanoid biosynthesis, as well as pathogen defense.
葡萄(Vitis)是世界上最有价值的水果作物之一,但昆虫取食会降低产量。了解昆虫的抗食性对于减轻这些损失至关重要。葡萄的野生北美种葡萄(Vitis labrusca)已被用于杂交葡萄的培育,以提高其对非生物和生物胁迫的抗性,使其成为可持续葡萄栽培的宝贵遗传资源。本研究评估了葡萄(V. labrusca acc. 'GREM4')和酿酒葡萄(Vitis vinifera cv. 'PN40024')对日本丽金龟(日本甲虫)取食的抗性,并鉴定了这种潜在抗性的形态和遗传适应性。
在 30 分钟至 19 小时的选择和非选择取食实验中,与 'PN40024'相比,'GREM4'对甲虫取食的抗性更强。'GREM4'的叶片平均表皮毛密度明显高于 'PN40024',而且甲虫更喜欢在表皮毛较少的叶片一侧取食。当甲虫取食两种叶片的表皮毛密度没有差异时,'GREM4'叶片的受损面积(3.29mm)明显小于 'PN40024'(9.80mm),这表明 'GREM4'的抗虫性除了表皮毛之外还有其他因素。比较转录组分析显示,与 'PN40024'相比,'GREM4'在 0 小时时对防御反应和次生代谢物生物合成基因的组成型(0 小时)表达更高,表明其具有更高的组成型防御能力。取食后,'GREM4'表达的差异基因(690 个)明显多于 'PN40024'(502 个),这表明 'GREM4'的反应更为广泛。在 'GREM4'中上调的基因富集于萜烯生物合成、类黄酮生物合成、植物激素信号转导和疾病防御相关功能,可能有助于提高对昆虫取食的防御,而在 'PN40024'中差异表达的基因则富集于木葡聚糖、细胞壁形成和钙离子结合。参与昆虫取食防御的大多数基因与 'GREM4'和 'PN40024'中的特定表达模式有关,但一些同源和基因组特异性基因也可能有助于赋予抗性。
我们的研究结果表明,'GREM4'对昆虫取食的抗性归因于多种因素的综合作用,包括表皮毛和与萜烯、类黄酮和苯丙烷生物合成以及病原体防御有关的基因的组成型和诱导型表达。
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