中规模蚊虫饲养设施的建立：白纹伊蚊（双翅目：蚊科）幼虫大量饲养单元的优化。

Establishment of a medium-scale mosquito facility: optimization of the larval mass-rearing unit for Aedes albopictus (Diptera: Culicidae).

机构信息

Department of Parasitology, Zhongshan School of Medicine, Sun Yat-sen University, Guangzhou, Guangdong, 510080, China.

Key Laboratory for Tropical Disease Control, Ministry of Education, Sun Yat-sen University, Guangzhou, Guangdong, 510080, China.

出版信息

Parasit Vectors. 2017 Nov 13;10(1):569. doi: 10.1186/s13071-017-2511-z.

DOI:10.1186/s13071-017-2511-z

PMID:29132425

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5683581/

Abstract

BACKGROUND

Standardized larval rearing units for mosquito production are essential for the establishment of a mass-rearing facility. Two larval rearing units, developed respectively by the Guangzhou Wolbaki Biotech Co. Ltd. (Wolbaki) and Insect Pest Control Laboratory, Joint FAO/IAEA Division of Nuclear Techniques in Food and Agriculture (FAO/IAEA-IPCL), are tested to assess their potential uses to mass-rear the larval stages of Aedes albopictus in support of the establishment of a medium-scale mosquito facility for the application of mosquito genetic control strategies.

METHODS

The triple Wolbachia-infected Ae. albopictus strain (HC strain) was used in this study. The effects of larval densities of two larval rearing trays (corresponding to 2.4, 3.0 and 3.6 larvae/cm) and tray size/position (top, middle and bottom layers) on the pupae production and larval survival were assessed when trays were stacked within the larval rearing units. The male pupae production, female pupae contamination after sex separation, and male mating competitiveness were also studied by using both larval rearing units in their entirety.

RESULTS

The optimal larval rearing density for Wolbaki-tray (Wol-tray) was 6,600 larvae (equal to 3.0 larvae/cm) and 18,000 larvae (3.6 larvae/cm) for the FAO/IAEA-IPCL tray (IAEA-tray). No significant difference in pupae production was observed when trays were stacked within top, middle or bottom layers for both units. At thirty-four hours after the first pupation, the average male pupae production was (0.89 × 10) for the Wol-unit and (3.16 × 10) for the IAEA-unit. No significant difference was observed in female pupae contamination between these two units. The HC males showed equal male mating competitiveness to wild type males for mating with wild type females in large cages, regardless of whether they were reared in the Wol-unit or IAEA-unit.

CONCLUSIONS

The current study has indicated that both the Wol-unit and IAEA-unit are suitable for larvae mass-rearing for Ae. albopictus. However, the IAEA-unit, with higher male production and less space required compared to the Wol-unit, is recommended to be used in support of the establishment of a medium-sized mosquito facility.

摘要

背景

标准化的蚊虫幼虫饲养单元对于建立大规模饲养设施至关重要。本研究分别使用广州沃巴克生物科技有限公司（Wolbaki）和粮农组织/国际原子能机构核技术在粮食和农业中的应用联合司昆虫害虫控制实验室（FAO/IAEA-IPCL）开发的两种幼虫饲养单元，来评估它们在大量饲养白纹伊蚊幼虫以支持建立中型规模蚊虫设施、应用蚊虫遗传控制策略方面的潜在用途。

方法

本研究使用三重感染沃尔巴克氏体的白纹伊蚊（HC 品系）。当将幼虫饲养单元中的饲养盘堆叠起来时，评估了两种饲养盘（分别对应于 2.4、3.0 和 3.6 条幼虫/cm）的幼虫密度以及盘的大小/位置（上层、中层和下层）对蛹产量和幼虫存活率的影响。还使用这两种幼虫饲养单元，研究了整体的雄蛹产量、性别分离后雌蛹污染以及雄虫交配竞争力。

结果

Wolbaki 饲养盘（Wol 盘）的最佳幼虫饲养密度为 6600 条幼虫（相当于 3.0 条幼虫/cm），FAO/IAEA-IPCL 饲养盘（IAEA 盘）的最佳幼虫饲养密度为 18000 条幼虫（3.6 条幼虫/cm）。对于这两个单元，当饲养盘堆叠在上层、中层或下层时，蛹产量没有显著差异。在第一次化蛹后 34 小时，Wol 单元的平均雄蛹产量为（0.89×10），IAEA 单元的平均雄蛹产量为（3.16×10）。这两个单元之间的雌蛹污染没有显著差异。HC 雄虫与野生型雄虫在大笼中与野生型雌虫交配时，表现出相同的交配竞争力，无论它们是在 Wol 单元还是 IAEA 单元中饲养。

结论

本研究表明，Wol 单元和 IAEA 单元均适用于白纹伊蚊幼虫的大规模饲养。然而，与 Wol 单元相比，IAEA 单元具有更高的雄虫产量和更少的空间需求，因此建议在支持建立中型规模蚊虫设施方面使用 IAEA 单元。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9e9f/5683581/fe2d053efb4f/13071_2017_2511_Fig1_HTML.jpg

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中规模蚊虫饲养设施的建立：白纹伊蚊（双翅目：蚊科）幼虫大量饲养单元的优化。

Establishment of a medium-scale mosquito facility: optimization of the larval mass-rearing unit for Aedes albopictus (Diptera: Culicidae).

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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