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套袋减少了‘鸭梨’果实采后的腐烂,并改变了果实表面真菌群落的多样性。

Fruit bagging reduces the postharvest decay and alters the diversity of fruit surface fungal community in 'Yali' pear.

机构信息

Institute of Biotechnology and Food Science, Hebei Academy of Agriculture and Forestry Sciences, Shijiazhuang, 050051, China.

Plant Genetic Engineering Center of Hebei Province, Shijiazhuang, 050051, China.

出版信息

BMC Microbiol. 2022 Oct 5;22(1):239. doi: 10.1186/s12866-022-02653-4.

DOI:10.1186/s12866-022-02653-4
PMID:36199024
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9533515/
Abstract

BACKGROUND

Fruit bagging is an effective technique for fruit protection in the orchard management. Bagging can create a micro-environment for fruit growth and affect fruit quality during storage, in which the diversity of microorganisms may play an important role. Therefore, various methods including biochemistry, analytical chemistry, and bioinformatics methods were used to reveal the influences of fruit bagging on postharvest fruit quality, physiological characters, decay and surface fungal community of 'Yali' pear fruit were investigated in this study.

RESULTS

Fruit bagging significantly decreased the postharvest decay after 15 days of ambient storage. There were no significant differences in fruit firmness, titratable acid and ethylene production rate between the fruit-bagging and non-bagging group after 15 days of storage, while the soluble solids contents (SSC) and respiration rate in non-bagging fruit was significantly higher than that in fruit-bagging after 15 days of storage. Furthermore, the surface microbes of pear were collected and determined by the new generation sequencing technology. The alpha diversity of fungi in non-bagging fruit decreased significantly after 15 days of storage, while there were no significant changes in bagging fruit. Ascomycota and Basidiomycota were the two major phyla detected in the bagging fruit, and the dominant fungal genera were Alternaria (23.7%), Mycosphaerella (17.25%), Vishniacozyma (16.14%), and Aureobasidium (10.51%) after 15 days of storage. For the non-bagging pear, Ascomycota was the only phylum detected, and the dominant genera was Pichia (83.32%) after 15 days of storage. The abundance of Pichia may be regarded as the biomarker to indicate the degree of fruit decay.

CONCLUSIONS

This study showed that fruit bagging could significantly reduce postharvest fruit decay and respiration rate of 'Yali' pear. Significant differences were found in fungal composition between bagging and non-bagging pear after storage for 0 or 15 days. Fruit bagging maintained the diversity of fungi on the fruit surface, increased the abundance of non-pathogenic fungi, and even antagonistic fungi such as Aureobasidium, Vishniacozyma, and Mycosphaerella. A reduction in the abundance of pathogenic fungi and incidence of postharvest decay during the storage of 'Yali' pear were also recorded. In conclusion, fruit-bagging changed the fungal diversity on fruit surface of 'Yali' pear, which had significant effect on reducing postharvest fruit decay, and thus prolong the storage period of 'Yali' pears. The future thrust of this study will focus on the isolation of fungi or bacteria from pear fruit surface and identify their roles in causing fruit decay and changing fruit quality during storage.

摘要

背景

果实套袋是果园管理中保护果实的有效技术。套袋可以为果实生长创造一个微环境,并影响果实贮藏期间的品质,其中微生物的多样性可能起着重要作用。因此,本研究采用生物化学、分析化学和生物信息学等方法,研究了果实套袋对‘鸭梨’果实采后品质、生理特性、腐烂和表面真菌群落的影响。

结果

果实套袋显著降低了常温贮藏 15 天后的采后腐烂率。贮藏 15 天后,套袋与不套袋果实的果实硬度、可滴定酸和乙烯释放率无显著差异,而不套袋果实的可溶性固形物含量(SSC)和呼吸速率显著高于套袋果实。此外,采用新一代测序技术收集和测定了梨的表面微生物。贮藏 15 天后,不套袋果实的真菌α多样性显著下降,而套袋果实无显著变化。套袋果实中检测到的主要菌门为子囊菌门和担子菌门,优势真菌属为链格孢属(23.7%)、球腔菌属(17.25%)、黏帚霉属(16.14%)和金龟子属(10.51%)。贮藏 15 天后,不套袋梨只检测到子囊菌门,优势菌属为毕赤酵母属(83.32%)。毕赤酵母属的丰度可作为果实腐烂程度的生物标志物。

结论

本研究表明,果实套袋可显著降低‘鸭梨’果实采后腐烂率和呼吸速率。贮藏 0 天或 15 天后,套袋和不套袋梨的真菌组成存在显著差异。果实套袋保持了果实表面真菌的多样性,增加了非致病性真菌的丰度,甚至增加了金龟子属、黏帚霉属和球腔菌属等拮抗真菌的丰度。贮藏期间‘鸭梨’果实致病性真菌丰度降低,腐烂率降低。总之,果实套袋改变了‘鸭梨’果实表面的真菌多样性,对降低采后果实腐烂率有显著效果,从而延长了‘鸭梨’果实的贮藏期。本研究的未来重点将放在从梨果实表面分离真菌或细菌,并确定其在果实腐烂和贮藏期间改变果实品质中的作用。

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